ERIA Research Project Report 2020, No · 2020. 8. 14. · ERIA Research Project Report 2020, No.07...
Transcript of ERIA Research Project Report 2020, No · 2020. 8. 14. · ERIA Research Project Report 2020, No.07...
ERIA Research Project Report 2020, No.07
Edited by
Shigeru Kimura
Han Phoumin
Leong Siew Meng
Prepared by the General Department of Energy, Ministry of Mines and
Energy of Cambodia
Supported by the Economic Research Institute for ASEAN and East Asia
Energy Efficiency and Conservation Master Plan of Cambodia
Economic Research Institute for ASEAN and East Asia (ERIA)
Sentral Senayan II 6th Floor
Jalan Asia Afrika no.8, Gelora Bung Karno
Senayan, Jakarta Pusat 10270
Indonesia
©Economic Research Institute for ASEAN and East Asia, 2020
ERIA Research Project Report FY2020 No. 07
Published in July 2020
All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form by any means electronic or mechanical without prior written notice to and permission from ERIA. The findings, interpretations, conclusions, and views expressed in their respective chapters are entirely those of the author/s and do not reflect the views and policies of the Economic Research Institute for ASEAN and East Asia, its Governing Board, Academic Advisory Council, or the institutions and governments they represent. Any error in content or citation in the respective chapters is the sole responsibility of the author/s. Material in this publication may be freely quoted or reprinted with proper acknowledgement.
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Preface
Cambodia’s fast economic growth since the 2000s has transformed the country into a market-based
economy and enabled it to join regional and global production networks. Garments, textiles, tourism, and
agriculture have been the country’s fastest-growing sectors, and these sectors have accounted for more
exports of manufacturing products and other primary high-quality value-added products to the
international market. Investments from around the globe into this region have been driven by a
favourable labour force, growth of connectivity and innovation, and regional political stability – driven by
peace and the stability of Cambodia’s political environment – and harmony amongst the members of the
Association of Southeast Asia Nations (ASEAN). Fast economic growth has also lifted the well-being of
Cambodia’s people through income generation and employment. One key factor behind this strong
economic growth was the fast growth of energy consumption during the same period. Energy demand
increased threefold, from 3.42 Mtoe in 2000 to an estimated 8.94 Mtoe by 2020. The Economic Research
Institute for ASEAN and East Asia (ERIA) forecasts a doubling of energy demand from 2020 to 2040, to
reach 15.25 Mtoe in 2040.
The Ministry of Mines and Energy (MME) of Cambodia realises the importance of acting quickly through
energy efficiency and conservation (EEC) to curb demand growth whilst maintaining economic growth.
The MME is grateful for ERIA’s technical support over the past 10 years in helping it to build the
foundations of the data and statistics and support the formulation of downstream energy policy
regulations and energy policy in Cambodia. This energy efficiency master attempts to define the legal and
organisational bases for energy efficiency activities, and suggest ways to create the conditions for
enabling Cambodia to reduce its energy consumption. It is hoped the master plan will also guide
investment on EEC through appropriate policies to attract foreign and domestic investors in EEC business
such as energy service companies and the promotion of efficient uses of energy appliance and energy
efficiency building.
On behalf of the ministry, I am very thankful to Prof Hidetoshi Nishimura, ERIA President, who honoured
my request for ERIA’s support to the MME in formulating the EEC Master Plan. I would like to thank the
experts of ERIA and the MME staff for their efforts in producing this important policy document. During
the project period, ERIA also conducted capacity-building training, such as on a basic understanding of
the EEC and energy service companies. Lastly, the MME would like to show its great appreciation to ERIA
for its technical and financial support in publishing this master plan.
HE Mr Suy Sem
Minister of Mines and Energy, Cambodia
July 2020
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Acknowledgements
The EEC (energy efficiency and conservation) Master Plan was developed by a working group comprising
teams from Cambodia and the Economic Research Institute for ASEAN and East Asia (ERIA). The
Cambodian team consisted of staff from the General Department of Energy of the Ministry of Mines and
Energy (MME), Cambodia. The ERIA team consisted of experts on legal framework, energy efficiency, and
EEC business development such as setting up of energy service companies (ESCOs). A series of
consultations were made with various local experts around the EEC in Cambodia. The feedback from these
consultations contributed to the understanding of international experts on the need to have the EEC and
set up the appropriate policy in this master plan. We would like to thank many people who the study
team consulted during the formulation of this master plan. We would like to acknowledge members of
the working group for their excellent work. We would also like to especially take this opportunity to
express our gratitude to the staff of the General Department of Energy, the General Department of
Petroleum, and Electricity of Cambodia for their cooperation in this project through their inputs of data
and knowledge.
Special acknowledgement is also given to Shigeru Kimura, Special Adviser on Energy Affairs to the
President of ERIA, for his excellent leadership of this project.
HE Mr Victor Jona
Director General
General Department of Energy
Ministry of Mines and Energy
July 2020
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Project Members
From the Ministry of Mines and Energy, Cambodia
HE Mr Victor Jona Director General, General Department of Energy
Mr Heng Kunleang Deputy Director General
Mr Tan Sokun Director, Department of Energy Development
Mr Kin Sothea Deputy Director, Department of Energy Development
Mr Sok Chandareth Deputy Director, of Energy Development
Mr Heang Theangseng Chief of Energy Statistics of Energy Development Department
From the Experts Team of the Economic Research Institute for ASEAN and East Asia
Mr Shigeru Kimura Special Advisor to the President for Energy Affairs, Energy Unit,
Research Department
Dr Han Phoumin Senior Energy Economist, Energy Unit, Research Department
Ir Leong Siew Meng Consultant, Green Technology Solutions PLT, Malaysia
Ir Lee Yuen How Managing Director, GBI Innovation Sdn Bhd, Malaysia
Ir Luk Chau Beng Industrial and Building Energy System Optimisation Expert, Malaysia
Ir Yau Chau Fong Managing Director, Duriane Professionals Sdn Bhd, Malaysia
We acknowledge the following parties for facilitating this case study: Daikin Malaysia Sdn Bhd (Branch
of Cambodia), Goh Lam Yong; Daikin Applied (Malaysia) Sdn Bhd, Chea Suei Keong; and GA Aircon,
Phnom Penh, Cambodia, Sokkheng Min.
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Contents
List of Figures and Tables viii
List of Abbreviations ix
Executive Summary x
Chapter 1 Legislative Framework 1
Han Phoumin and Shigeru Kimura
Chapter 2 Energy Service Company 7
Lee Yuen How
Chapter 3 Energy Managers 19
Luk Chau Beng
Chapter 4 Standards and Labelling 33
Yau Chau Fong
Chapter 5 Education and Campaigns 46
Leong Siew Meng
Chapter 6 Data Collection for Establishment of Energy Efficiency Indicators 62
Leong Siew Meng
Chapter 7 Conclusions and Policy Recommendations 78
Shigeru Kimura, Leong Siew Meng, and Han Phoumin
Annex A Case Study: Potential Energy Savings of a Hotel’s Chilled-Water Air-conditioning System
82
Leong Siew Meng and Lee Yuen How
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List of Figures
Figure 1.1 Draft Institutional Chart of the EEC 3 Figure 2.1 Scope of ESCO Services 8 Figure 2.2 Sample of ESCO Application Form (page 1) 10 Figure 2.3 Sample of ESCO Application Form (page 2) 11 Figure 2.4 Shared Savings EPC Business Model 12 Figure 2.5 Guaranteed Savings EPC Business Model 13 Figure 2.6 ESCO EPC Business Model 14 Figure 3.1 Functions of Energy Managers under the Regulations 21 Figure 3.2 Overview of Implementation of Energy Managers’ Programme 25 Figure 3.3 Sample Syllabus for Energy Manager Certification Course 25 Figure 3.4 Process of Certification of Energy Managers 26 Figure 4.1 Interrelation between Institutions 36 Figure 4.2 Registration Process of MEPS and Energy Labelling of Electrical
Appliances 41
Figure 4.3 Flow Diagram of the MEPS and Energy Labelling Programme 43 Figure 5.1 Structure of GDE’s roles in Implementing EEC Education and Campaign 47 Figure 5.2 Cluster of EEC Education and Campaign Activities 48 Figure 5.3 Methods of Media Campaigns 52 Figure 5.4 Electricity Consumption of a Typical Home vs an Energy-efficient
Home 54
Figure 5.5 Home Energy Report Comparing Electricity Consumption in the Same Area
58
Figure 5.6 Example of Deriving the Average Monthly Electricity Consumption in a Neighbourhood
59
Figure 5.7 Comparison of Personal Electricity Consumption of the Same Period in the Preceding Year
60
Figure 6.1 Energy Consumption of Cambodia in 2018 65 Figure 6.2 Overview of Energy Indicators Pyramid 67 Figure 6.3 Example on Validation of Data based on Analysis of BEI Values for
Hospitals 68
Figure 6.4 Example on Validation of Data based on Analysis of BEI Values for Retail Malls
69
Figure 6.5 Process of Data Collection and Establishment of EEIs 69 Figure 6.6 Pyramid of Commercial Sector Indicators 70 Figure 6.7 Pyramid of Industry Sector Indicators for Sub-sectors 72 Figure 6.8 Typical Energy Flow and Utilisation in Industrial Production Process 73 Figure 6.9 Pyramid of Residential Sector Indicators 74 Figure A1 Monthly Electricity Consumption (2018–2019) 83 Figure A2 Average Daily Electricity Consumption (2018–2019) 84 Figure A3 Average Daily Chilled-water Generation, in RT (2018–2019) 84 Figure A4 Estimated Daily Chiller Load Profile Derived from Chilled-water
Generation, in RT 85
Figure A5 Cash Flow for Case Study 87 Figure A6 Comparison of Energy Performance of Chillers at Part-load and Full-
load Operations between Magnetic Chillers and Conventional Chillers 89
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List of Tables
Table 2.1 Road Map Milestone for ESCOs with Leading and Responsible Organisations 17
Table 3.1 Road Map Milestone for Energy Managers with Leading and Responsible Organisations
32
Table 4.1 List of Countries that Adopted Energy Labelling 34
Table 4.2 Selected Countries’ Appliances with MEPS and Energy Labelling and their Status
37
Table 4.3 Road Map and Implementation Programme for MEPS and Energy Labelling 44
Table 5.1 Tips for Efficient Use of Air Conditioners 55
Table 5.2 Tips for Efficient Use of Lighting 55
Table 5.3 Tips for Efficient Use of Electric and Microwave Ovens 56
Table 5.4 Tips for Efficient Use of Home Entertainment Devices 56
Table 5.5 Tips for Efficient Use of Refrigerators 56
Table 5.6 Tips for Efficient Use of Electric Instant Water Heater 57
Table 5.7 Education and Campaign Road-map Activities (2020–2025) 60
Table 6.1 Comparison of Threshold Values in Some ASEAN Countries and Japan 63
Table 6.2 Suggested Minimum BEI Values for Building Sub-sectors 71
Table 6.3 Recommended Road Map for 2020–2025 Activities 76
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List of Abbreviations
AJEEP ASEAN–Japan Energy Efficiency Partnership
ASEAN
ASHRAE
Association of Southeast Asian Nations
American Society of Heating, Refrigerating and Air-conditioning Engineers
BEI
CPD
DoET&EBP
building energy intensity
continuous professional development
Department of Energy Technique and Energy Business Policy
EDC Electricite Du Cambodge
EEC
EEI
EEM
energy efficiency and conservation
energy efficiency indicator
energy efficient management
ECCJ
EMAK
EPC
Energy Efficiency Center of Japan
Energy Management Action Network
energy performance contract/contracting
ESCO energy service company
GDE
GDP
General Department of Energy
gross domestic product
GHG greenhouse gas
IEA International Energy Agency
IEC International Electrotechnical Commission
IECEE CB IECEE CB Scheme (IEC System of Conformity Assessment Schemes for Electrotechnical Equipment and Components) Certification Body Scheme
IRR internal rate of return
ISC The Institute of Standards of Cambodia
kWh
kW/RT
kilowatt-hour
kilowatt per refrigeration ton
LED light-emitting diodes
MEPS
mil MJ/y
minimum energy performance standard
million megajoules per year
MME Ministry of Mines and Energy, Cambodia
MRA mutual recognition agreement
SWO Standard-writing Organisation
S&L standard and labelling
TFC
TFEC
total final consumption
total final energy consumption
UNIDO United Nations Industrial Development Organization
x
Executive Summary
Energy consumption in Cambodia has been increasing rapidly. According to the Energy Demand and
Supply of Cambodia 2010–2018(2019)1, one of the energy research reports of the Economic Research
Institute for ASEAN and East Asia (ERIA), total final energy consumption (TFEC) grew at 7.2% per annum
in 2010–2018. However, its elasticity over gross domestic product (GDP) was 1 because of the 7.2%
growth rate of GDP in the same period. The TFEC includes biomass, whose share was significant in
Cambodia (biomass share over the TFEC was still 25.5% in 2018). The growth rates of commercial energy,
such as oil and electricity, in 2010–2018 were 8.1% and 18.3% per year, respectively, which were much
higher than the TFEC. In the future, biomass’s 25.5% share in the TFEC will surely be replaced by
commercial energy, such as oil and electricity. Thus, Cambodia must formulate and implement energy
efficiency and conservation (EEC) policies and programmes to curb commercial energy consumption.
Unfortunately, the country has not formulated its EEC programme. Consequently, the General
Department of Energy (GDE), Ministry of Mines and Energy, ERIA to come up with the EEC Master Plan
for Cambodia.
The GDE plans to formulate many EEC policies and programmes but ERIA just focused on the following
five EEC policies and programmes due to their effectiveness, ‘quick-acting’, and low cost: (i) energy service
company (ESCO), (ii) growing of energy managers, (iii) standard and labelling system, (iv) education and
campaign, and (v) preparation of energy efficiency indicators (EEIs). ERIA also prepared a 5-year road map
(2020–2025) for each EEC policy and programme mentioned above.
Fortunately, energy prices, such as electricity, in Cambodia are relatively higher than those of its
neighbouring countries due to the absence of energy subsidies. Thus, owners of many factories and
buildings, which have higher energy costs, would like to reduce these costs. Given this situation, the EEC
Master Plan firstly suggests that the GDE start installing ESCOs in Cambodia’s energy market. The GDE will
simply prepare the qualifications of ESCOs and license those that submit their application forms to the
GDE. The industry and commercial sectors have a remarkable energy-saving potential, and ESCOs will
realise such saving potential by applying their practical expertise and experience on the EEC. However,
during the initial stage, the GDE will support ESCOs by providing them with business opportunities –
retrofitting existing government buildings and creating advanced EEC designs for new ones.
An ESCO usually consists of energy managers who hold an EEC certificate from a domestic or foreign
organisation, such as the Energy Efficiency Center of Japan (ECCJ). Energy managers are key role players
in promoting the EEC in Cambodia. Because of their currently limited number, the GDE must increase or
grow energy managers. Because of new EEC regulations which will be formulated in a few years, energy-
intensive factories and buildings will be designated and mandated to assign energy managers to monitor
the premises’ energy consumption. Some energy managers will work for ESCOs and engage in EEC
consulting work. Others will be independent and engage in energy audit work designated by the GDE. The
EEC Master Plan targets 100 energy managers by 2025, and an association of energy managers will be a
1 Ministry of Mines and Energy, Cambodia and ERIA (2019), Energy Demand and Supply of Cambodia 2010–2018. Jakarta: ERIA. Available at: https://www.eria.org/publications/energy-demand-and-supply-of-cambodia-2010-2018/
xi
good place to organise regular advanced EEC lectures for existing energy mangers in Cambodia with the
strong support of the GDE.
Households in Cambodia will buy additional appliances, such as refrigerators, air conditioners, washing
machines, and cooking equipment like rice cookers and microwave ovens. Their criteria for buying
appliances are capacity and price. So far, they do not know the energy efficiency level of each appliance
because of the absence of a standard and labelling (S&L) system in Cambodia. If households recognise
the energy efficiency level of each appliance, their criteria in buying appliances will increase from two to
three: capacity, price, and energy efficiency. In other words, they will buy more energy-efficient
appliances, and this behaviour will surely realise energy savings in the country’s residential sector. But if
the GDE will promote an S&L system, it must allocate a large budget to implement such a system, which
involves establishing testing laboratories and issuing labels. Thus, a long-term plan is needed to achieve
an S&L system in Cambodia.
The GDE staff in charge of the EEC is aware of its promotion, but not the ordinary people. Thus, education
and campaign on the EEC are particularly important for the department. Through this programme, the
GDE must encourage people to understand the importance of the EEC and its practice, such as switching
off electricity frequently, minimising standby power, providing simple shadings to reduce solar heat gains,
etc. Also, the education and campaign programme should be linked to the S&L system. EEC education and
campaigns are the first step for the GDE to promote the EEC in Cambodia and remarkable energy savings
can be expected across the sectors, especially the residential sector.
To measure the amount of energy savings resulting from the implementation of EEC policies and
programmes, we need benchmarks or, in other words, the current energy consumption level of
appliances, equipment, factories, buildings, and households. The benchmarks are called energy efficiency
indicators (EEIs). Generally, the EEIs are estimated based on survey results, which are detailed energy
consumption across the sectors. The survey will be done under a new EEC regulation because before the
survey, factories and buildings should report their energy consumption data to the GDE. The EEIs will also
be updated every 3 to 5 years.
Many East Asia Summit countries have formulated an EEC Act, under which they promote energy savings
by implementing EEC action plans. Parallel to installing ESCOs, growing energy managers, and
implementing standards and campaigns, the GDE must formulate an EEC Act for S&L and prepare the EEIs.
An EEC Act will make voluntary EEC policies and programmes mandatory. It comes with reasonable budget
allocation to implement EEC policies and programmes, according to the road map specified by the EEC
Master Plan.
1
Chapter 1
Legislative Framework
Han Phoumin and Shigeru Kimura
1.Introduction
From 1998 to 2018, Cambodia had enjoyed a steady economic growth of 8%, and remarkably achieved a
lower middle–income status in 2015 (World Bank, 2020). Strong economic growth was also recorded at
7.1% in 2019. Due to COVID-19, growth is predicted to slow down at 2.5% throughout 2020. However, it
will recover by early 2021 when the world economy also starts to recover from the economic shock
because of preventive measures affecting the industries and tourism. Energy demand has been known to
be the input for economic growth, and its association is very strong. As Cambodia’s economy grows, so
does its energy demand increase. Based on ERIA’s energy outlook and saving potential in East Asia (Kimura
and Han, 2019), final energy consumption is expected to double in 2015–2040, during which the industry
sector is expected to grow at an average rate of 3.5%, reaching 2.41 Mtoe in 2040, an increase from 1.03
Mtoe in 2015. For the residential and commercial sectors, energy demand is predicted to grow at an
average rate of 2% in 2015–2040, reaching 5.67 Mtoe in 2040, an increase from 3.45 Mtoe in 2015.
Transport will mark the highest growth rate of 3.9% in 2015–2040, reaching 3.59 Mtoe in 2040, an
increase from 1.39 Mtoe in 2015.
As energy demand increases, energy efficiency and conservation (EEC) becomes significant in curbing
demand growth whilst maintaining economic growth because the same amount of energy use will lead
to a large quantity of output in the economy. Energy efficiency is also known as the hidden fuel and can
be translated as an energy resource to the nation as it will become energy available for other economic
activities and supply the greater population. Savings in electricity consumption are even more significant
as every kilowatt-hour unit saved would result in greater savings in fuel consumption, such as coal and
gas, to generate power. The Government of Cambodia now acts swiftly to prepare the necessary power
development plan to meet the growing electricity demand in all sectors. Thus, the energy efficiency plan
will help avoid building more power plants, as well as help save investment money for the economy.
Considering the fast-growing energy demand, appropriate energy efficiency regulations will be needed.
Below is the content of the Cambodia Energy Efficiency Regulation to help the Ministry of Mines and
Energy (MME) formulate related sub-degrees or regulations.
2. Content of Energy Efficiency Regulations
2.1. Objective and legal framework of energy efficiency regulations
The sub-degree or regulations on energy efficiency will define the legal and organisational basis for
activities in the field of energy efficiency and aim to create conditions to reduce energy consumption. In
this case, the sub-degree or regulations will instruct the MME and involved agencies to develop a
comprehensive policy and regulatory framework to achieve energy efficiency in all sectors. Specifically,
this regulation aims to promote energy efficiency as part of the country’s sustainable development policy
by
2
• applying a system of activities and measures to improve energy efficiency, especially for the end-
uses of energy;
• introducing schemes of obligations for energy savings;
• developing the market, and encouraging the provision of, energy efficiency services; and
• introducing financial mechanisms and schemes supporting the fulfilment of the national objective
of energy efficiency.
The MME will need to have precise and timely data on energy efficiency to establish energy policy targets
and programmes/actions in all sectors. At the first step, it will need to collect energy efficiency data from
line ministries/agencies/sectors (administrative or secondary data). In the future, the MME and involved
agencies will need to have regular energy consumption surveys of the household, commercial, industry,
and transport sectors for the precise targets and policy of energy efficiency.
The availability of accurate, up-to-date information on energy efficiency is essential for assessing the
impact of energy savings and contribution to the reduction of greenhouse gas (GHG) emissions. This
information will support the government’s commitment to report GHG emissions, implement the Kyoto
Protocol, and fulfil the commitment during the 2015 United Nations Climate Change Conference or COP
21. The sub-degree or regulations follow the government’s initiatives and other ongoing activities that
aim to promote energy efficiency in all sectors. The sub-degree or regulations should be adopted
following the Prime Minister’s order, laying down the procedures for the MME to exercise/implement
powers.
To quickly shift to the required implementing stage of the EEC in Cambodia, this regulation focuses on the
following four major EEC topics, plus penalty:
1) Energy management system to include energy management and reporting designated
premises, education and campaigns, and energy managers;
2) Standard and labelling;
3) Establishment of ESCOs;
4) Building energy efficiency code/guidelines; and
5) Penalty, if entities do not follow this regulation.
2.2 Institutional framework
The GDE–MME is in charge of promoting the EEC. This EEC Master Plan for Cambodia recommends that
the GDE formulate new sections for the energy efficiency department to implement EEC activities in
Cambodia, according to this regulatory framework. Figure 1.1 is a draft institutional chart of the new
sections under the energy efficiency department of the GDE.
3
Figure 1.1 Draft Institutional Chart of the EEC
EE = energy efficiency, EEC = energy efficiency and conservation, ESCO = energy service company, GDE = General Department of Energy. Source: Authors’ suggestion.
The four sections shown in Figure 1.1 correspond to the four EEC topics mentioned above. The roles of
the four sections are specified below.
2.3 Energy management system
The energy management system aims to establish a structure and system for the implementation of plans
to improve energy performance, including energy efficiency, and effective management and reporting of
energy use in the commercial and industry sectors in Cambodia.
2.3.1 Energy management and reporting of designated premises
Factories or buildings that consume energy more than or equal to 3,000,000 kWh/year (or 10,800
MJ/year) shall be classified as designated premises, and shall be required to engage an energy manager
to organise energy management, implement energy efficiency measures, and submit an energy
management report for the respective designated premises to the Energy Management section under
the General Department of Energy.
The Energy Management section shall compile, collate, validate, and analyse the energy consumption
data reported in the energy management reports, and establish energy efficiency indicators (EEIs) and
energy statistics for the respective sub-sectors of the commercial and industry sectors.
2.3.2. Education and campaigns
Education and promotion campaigns are important in reaching out to the management and practicing
professionals of the commercial and industry sectors, government departments, and the public through
a cluster of programme activities. These activities include media campaigns, stakeholders’ engagement,
holding of technical forums, the publication of pamphlets and guidelines, incorporation of energy
efficiency syllabus in the education system, publicity campaigns such as national energy awards, etc. The
Energy Management section is also in charge of this action plan.
2.3.3 Energy managers
As part of energy management, a designated building and/or factory should engage an energy manager,
either through an externally sourced or internally developed programme, to ensure that the use of energy
in such a building is being managed efficiently. To achieve this, the energy manager needs to set
objectives, targets, and plans to achieve such planned targets, besides reporting to the management of
GDE
EE Department
Standard &
Labelling
Building EE
Code ESCO Energy
Management
4
the building and the relevant government authorities. The energy manager should set up an in-house
energy management committee or task force in the designated premises to collectively manage and
reduce energy consumption. Thus, he or she should be a competent and trained person with management
skills, technical knowledge and skills, and is familiar with EEC practices. The Energy Management section
is also in charge of accepting registration forms of energy manager candidates, assessing their application,
licensing the candidates, and updating the certification through regular capacity-building trainings.
2.4. Labelling and standards
As part of the energy efficiency measures, the use of electrical equipment and appliances is
recommended to satisfy the requirements specified in the minimum energy performance standards
(MEPS). With MEPS in place, an energy labelling system shall be applied, and registration of equipment
and appliances shall be done based on the labelling categories and criteria. This would set an energy
benchmark for the equipment and appliances to be purchased and utilised by users. Therefore, any
equipment or appliance that meets all the requirements of efficient electricity use shall be affixed with
an efficiency rating label in such a form and manner as may be determined by the MME. The standard
and labelling (S&L) section is in charge of formulating MEPS criteria of listed appliances and providing
energy efficiency labels in collaboration with the Cambodia National Laboratory that verifies MEPS.
2.5 Establishment of energy service companies
Energy service companies (ESCOs) are established to facilitate the uptake of efficient management of
energy use in Cambodia through the provision of comprehensive and competent services in energy
solutions to buildings and factories. The main goal is to benefit from the implementation of energy
efficiency measures.
2.5.1 Licensing/registration requirements
Licensing/registration requirements aim to enhance the professionalism and quality of services offered
by ESCOs. This will instil confidence in the energy services sector and promote the growth of the industry.
2.5.2 Energy auditing and energy performance contract
An energy audit is a systematic checking and reviewing procedure to obtain adequate information on the
energy consumption profile of a building or an industrial premise to establish its baseline energy
consumption before any EEC measure is installed. In addition, the energy audit will identify and quantify
cost-effective energy-saving opportunities and report the findings.
An energy performance contract (EPC) is a turnkey service offered by ESCOs to the building or factory
owner. The ESCO would finance the installation of energy-saving measures, monitor, and verify energy
savings, which shall be shared with the premise owner to recover the costs of financing the project under
an EPC agreement.
2.5.3 Financing mechanism
A creative financing mechanism and business model designed to encourage investments in energy
efficiency, and the energy performance contract (EPC) needs to be established. Financing institutions play
5
a key role in establishing and facilitating a business environment for the EPC linking ESCOs, as EEC turnkey
service providers, with business entities. The government would play an important role in ensuring that
only creditable and competent ESCOs with some financing capabilities would be allowed toregister to
offer their services.
2.6. Building energy efficiency code and guidelines
Establishing building energy efficiency code and guidelines is important for the implementation of energy
efficiency in buildings in view of the rapid development experienced in the country. The criteria that
require compliance with the code and guidelines shall be based on the following:
Any building that has a gross floor area exceeding 2,000 square metres shall be required to submit details
of code compliance to the Building Energy Efficiency Code section for approval.
The qualified professional appointed by the building owner shall declare that he/she has taken diligent
steps to incorporate energy efficiency design measures to comply with the energy intensity requirements
of the proposed building.
2.7 Penalty
For effective implementation, the penalty clause, which is important in the energy efficiency sub-degree
or regulations, should state that an obliged person who fails to fulfil the determined energy efficiency
target for annual new energy savings of a specified amount shall be imposed a fine or a proprietary
sanction of a certain amount. For example, the owner of a designated building for hotels or industries,
who fails to realise energy savings shall be imposed a fine or a proprietary sanction. The four sections
under the energy efficiency department also executes the penalty to the designated premises and ESCOs
if they fail to comply with this regulation.
3. Conclusion
The legal framework, such as the sub-degree or regulations on energy efficiency, is an important push
factor in establishing mandatory requirements for efficient energy management. It also aims to empower
the department or agency tasked with responsibilities to implement EEC plans and, consequently, achieve
EEC for Cambodia. For the private sector, a top–down approach requires top management or company
owners to undertake efficient energy management practices. The legal framework would require business
operations that exceed a certain threshold value of annual energy consumption to adopt an energy
management system or practices. The results of energy efficiency practices and energy productivity will
eventually benefit business operations by cutting energy costs. The energy efficiency regulation may not
be applicable to the residential sector except for the S&L system, which would require households to
recognise energy-efficient appliances. Similarly, building codes will also cover the commercial sector in
terms of energy-efficient buildings. It is also important to create the EEC culture by (i) incorporating
energy efficiency subjects in the school curriculum, (ii) conducting energy efficiency promotional
campaigns for the public in the residential sector, and (iii) organising awareness and capacity-building
training programmes for the commercial and industry sectors. Finally, promoting and adopting EEC
measures and practices will accelerate the achievement of sustainable development in Cambodia.
6
References
World Bank (2020), ‘The World Bank in Cambodia: The Overview’,
https://www.worldbank.org/en/country/cambodia/overview (accessed 20 April 2020).
Kimura, S. and P. Han (ed.) (2019), Energy Outlook and Energy Saving Potential for East Asia. Jakarta:
Economic Research Institute for ASEAN and East Asia.
7
Chapter 2
Energy Service Company
Lee Yuen How
1. Introduction
1.1. What is an energy service company?
Energy prices in Cambodia, especially that of electricity, are marketed without counterproductive
subsidies as far as energy efficiency is concerned. Accordingly, energy (electricity) cost seems to cost more
than that of neighbouring countries, such as Thailand and Viet Nam. Thus, the application of economic
efficiency policy to promote energy efficiency and conservation (EEC) is one of the options in Cambodia.
ESCO stands for energy service company. It operates a business by providing technologies with the
necessary financing to energy users to replace or improve existing energy facilities to save energy. An
ESCO will provide services as a one-stop solution for energy efficiency projects, which will ease project
implementation as the client does not need to manage all the technical stages in project development,
procurement, and commissioning. The ESCO retrieves the investment with the profit generated from the
energy saved. On the other hand, it can be a consultancy company specialising in energy audits or energy
monitoring services or equipment suppliers of energy-efficient equipment having competency in EEC.
According to the International Energy Agency (IEA) report, the value of the global ESCO market grew 8%
to US$28.6 billion in 2017, up from US$26.8 billion in 2016. China continues to underpin the global ESCO
market, growing at 11% to US$16.8 billion in 2017. The market in the United States, where ESCOs have
been operating for well over 30 years, grew to US$7.6 billion in 2017. In Europe, the ESCO market remains
somewhat underdeveloped compared to other major regions, representing 10% of the global total.
ESCOs have a huge potential role to play in reducing global energy consumption and, therefore,
greenhouse gas (GHG) emissions. They could also play a key role in addressing energy shortages and price
increases. ESCOs could be a particularly important force for change in developing countries and countries
in transition for various reasons.
1.2. Scope of services of ESCOs
ESCOs provide – either directly or through experienced subcontractors – all services identified by the
organisation as needed to implement the energy efficiency retrofit. ESCOs present a comprehensive plan
to maximise energy savings whilst meeting the customer’s specific facility requirements. ESCOs normally
design the project to include multiple conservation measures and to account for interfacing with existing
installations.
The scope of ESCO services can be divided into four main categories: (i) energy audit/advisory, (ii) finance,
(iii) monitoring, and (iv) procurement.
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Figure 2.1: Scope of ESCO Services
ESCO = energy service company. Source: Jensen (2017).
3. Fundamental operational features of ESCOs
ESCOs have four fundamental operational features. Firstly, an ESCO guarantees energy savings whilst
getting the same level of services at a lower energy cost through the implementation of an energy
efficiency project. This performance guarantee can revolve around the actual flow of energy savings from
a project, stipulating that the energy savings will be sufficient to repay monthly debt service costs for an
efficiency project or ensure the same level of energy service at a reduced cost.
Secondly, the compensation of ESCOs is directly tied to the energy savings achieved and, therefore,
performance.
Thirdly, ESCOs typically directly finance, or assist in arranging financing, for the installation of the
efficiency or energy project to be implemented by providing a savings guarantee.
Fourthly, ESCOs tend to retain an ongoing operational role in measuring and verifying the savings over
the financing term. Broadly, the ESCO model can be especially attractive to those considering structural
rehabilitation of existing buildings that also focus on energy efficiency retrofits. ESCOs can be an effective
instrument in developing the skilled professional job market and stimulating the energy efficiency
business in Cambodia.
Payments adjusted tosavings, i.e. no incremental cost/off-balance sheet
Performance monitoringOptimisationReportingBilling
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2. Registration and Licensing
The objective of ESCO registration and licensing is to improve the professionalism and quality of services
offered by ESCOs to clients. This will enhance confidence and trust in the energy services sector and
promote the growth and development of the ESCO industry.
The ESCO registration has the following benefits:
• Developing professional and qualified ESCOs,
• Enhancing the standing and recognition of ESCOs,
• Preventing false claims amongst industry players,
• Regulating and monitoring the services of ESCOs to the public, and
• Arranging and assisting the promotion of ESCO services.
Potential registration and licensing criteria could include a range of services offered, the presence of
qualified personnel like the energy manager, financing and project management capabilities,
technological and project design capabilities, and measurement and verification capabilities.
With the registration and licensing in place, the government can monitor the quantity and quality of
registered ESCOs per year, including the number of audits and implementation of energy performance
contracts (EPCs) in the industry. With the information obtained, the government can report the reduction
in carbon dioxide emissions and energy savings. All ESCO registration shall be valid for at least 1 year with
a yearly renewal requirement. Due to changes of staff over time,yearly renewal should be required to
ensure that an ESCO has a qualified person in the company. Continuous effort to conduct training and
certification for individuals within the ESCO industry, such as continuous professional development (CPD)
approach, could be considered.
3. Role of the General Department of Energy
The General Department Energy (GDE) has an important role in ensuring the development of ESCOs in
Cambodia. One of its most important roles is to promote the EPCs in government and iconic buildings.
This is to improve the energy use of buildings in the country and highlight the benefits of energy efficiency
design in new and existing buildings. By taking a lead role such energy efficiency projects in government
buildings will yield better results. The government can showcase successful EEC implementation and
encourage more entities of the private sector to participate and create the demand for ESCO services.
The GDE has the following roles to ensure ESCO establishment and growth in Cambodia:
• Capacity building, such as training to introduce best practices to local ESCOs to increase
competency and knowledge;
• Formulating energy efficiency programmes and laws and regulations;
• Engaging with the private sector to participate in the EPCs and create a market for ESCOs;
• Promoting the development of a standardised contract and monitoring and verification protocols,
such as the International Performance Measurement and Verification Protocol, to improve the
credibility of ESCOs;
• Creating awareness by sharing success stories of public sector energy efficiency projects;
• Establishing a good registration and licensing process for ESCOs to ensure their competence and
reliability;
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• Encouraging joint ventures between foreign and local ESCOs to improve the latter’s knowledge
and experience in implementing ESCO projects.
3.1. Sample ESCO application form
Figures 2.2 and 2.3 illustrates the form for ESCO registration and application. The details may be
adjusted to suit Cambodian requirements.
Figure 2.2 Sample of ESCO Application Form (page 1)
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Figure 2.3 Sample of ESCO Application Form (page 2)
4. Financial Incentives
Financing support structures and funding mechanisms are vital to the success of the ESCO industry and
the development of initial ESCO projects in the country. They assist in reducing the initial high costs and
risks associated with the project. The governments of most developing countries may not be able to take
on this task. However, the Cambodian government should invite international institutions like the World
Bank, the Global Environmental Facility, and the Asian Development Bank to support ESCOs financially in
the country during the early stages. However, this is only a short-term solution and should be considered
as a kick-start before the domestic commercial banks become interested and willing to fund the local
ESCOs. It is important to ensure that international organisations should not compete with domestic
commercial banks for profitable ESCO projects once domestic banks are willing and able to participate in
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ESCO financing. Once this occurs, international agencies and banks could play a secondary role in
financing less profitable projects.
For the long-term success of ESCOs, domestic commercial banks must eventually play a role in financing
ESCO projects. This requires institutional change and, therefore, a sustained effort over time. For
example, domestic banks – as part of their environmental, social, and corporate governance – can
introduce reduced interest rates in financial loans for energy efficiency projects. The banks can also
introduce capacity building for their bank staff and other stakeholders to understand energy-efficiency
financing through ESCOs.
Some other financial incentives can be through income tax exemption or reduction to encourage
foreign ESCOs to partner with local ESCOs for knowledge transfer. The government can also exempt duties
on imports of energy-efficient equipment for EEC projects.
5. ESCO Business Model and Case Study
5.1. Energy performance contracting
One key element to promote and encourage investment in energy efficiency in buildings and industries is
through energy performance contracting (EPC) undertaken by ESCOs. Under the EPC, ESCOs would design
and install energy-efficient systems/equipment for clients in the public, industry, and commercial sectors.
ESCOs’ remuneration is based on the amount of energy savings obtained from the retrofitting of the
energy-efficient systems. After the term of the contract, the subsequent value of the energy savings
would entirely belong to the client. ESCOs have been successfully using this model that has been operated
in many developed countries for years.
ESCO business models can be divided into two main financial models: shared savings contracts and
guaranteed savings contract.
5.2. ESCO business model: Shared savings EPC
Figure 2.4 Shared Savings EPC Business Model
EPC = energy performance contract/contracting, ESCO = energy service company. Source: International Energy Agency (IEA) website, https://www.iea.org/
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With shared savings EPC, the ESCO finances the implementation of energy conservation measures at the
customer’s facilities. Measured cost savings during the contract period are shared between the client who
owns the facility and the ESCO. Usually, the contract specifies that a percentage of the obtained savings
goes to the ESCO, which was previously defined by the client and the ESCO. This percentage is highly
dependent on factors like the length of the project and project risks.
ESCOs often use a shared savings model, where they are paid a percentage of the costs they save for their
client. Shared savings is a more attractive payment method because of its win-win nature. This is
particularly relevant for energy efficiency projects. In shared savings projects, ESCOs finance the
investment. In such a case, ESCOs take on the performance and credit risks. Through this business model,
energy users, energy and technology services companies, financial institutions, and environmental
protection workers together create a win-win situation.
5.3. ESCO business model: Guaranteed savings EPC
Figure 2.5 Guaranteed Savings EPC Business Model
EPC = energy performance contract/contracting, ESCO = energy service company. Source: International Energy Agency (IEA) website, https://www.iea.org/.
In guaranteed savings EPC, the ESCO assumes the risk of the project’s performance. The client obtains a
bank loan or uses its equity to pay contractually determined fees to the ESCO and the bank and keeps the
difference. The ESCO will guarantee a minimum energy savings level (percentage); if savings exceed the
guaranteed level, the ESCO or the customer can absorb the savings, depending on the method of payment
agreed. Fixed payment contracts mean that all savings belong to the customer whilst payment by a
percentage of savings means that all savings beside the ones guaranteed to the client are paid to the
ESCO.
Generally, the ESCO business model is for the energy users to improve energy efficiency, reduce energy
costs, avoid incurring additional project costs, increase the company's turnover and profitability with the
help of financial institutions to ease the financial burden, and contribute to environmental protection and
sustainable development.
Demonstration programmes in the public and the private sectors increase awareness of energy efficiency
and the role of ESCOs. They also increase ESCO capacity and are key to market creation. Government
project and provides
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demonstration programmes have been central to ESCO success in developed countries. Government
buildings are one of the biggest users of electricity in the world. To promote ESCOs, governments should
undertake demonstration projects in public buildings but should not limit these to the public sector.
Demonstration projects in various industry sectors and utilities would be very helpful in promoting ESCO
success. The government could play a key role in identifying industrial customers or groups of customers.
It goes through some of the first steps in terms of getting the client’s commitment, defining their
contracting and financing terms, getting basic information on their energy cost and consumption and use
characteristics, and then delivering to the ESCO community a qualified and decision-ready customer.
5.4. How to implement EPC in government buildings
1) Request for proposals, shortlist, and engage the services of an ESCO for an energy efficiency
improvement project in a government building.
2) Perform an energy audit at a facility to evaluate the level of savings that can be accomplished.
3) The ESCO will offer to implement and finance the project.
4) Guarantee the savings over an agreed term
5) The actual amount to be paid will be based on the agreed sharing value between the ESCO and
the owner of the government facility.
6) After the agreement ends, the ownership of all the equipment and system installed at the facility
will be transferred to the government.
7) The government will register and license the ESCO.
Figure 2.6 ESCO EPC Business Model
EPC = energy performance contract, ESCO = energy service company.
Source: Umar (2014).
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5.5. Case study: Shared savings EPC hospital project
5.5.1 Project information
The EPC case study involved a hospital with 548 beds using the shared savings business model. The
hospital was built in 1987 with a gross floor area of 44,800 m2. The average electricity tariff is
US$0.108/kWh. The EPC project scope includes the retrofit and upgrade of the chiller plant system and
the LED (light-emitting diodes) lighting. The project was completed within 30 weeks with an EPC contract
of 8 years where the savings are split – 80% to the ESCO and 20% to the client. After the contract period,
the asset would be transferred to the client without any cost, and the total 100% savings would be
enjoyed by the client. The total EPC project cost was about US$850,000.00, consisting of engineering,
consultancy, measurement and verification, procurement of the equipment, and project management
and supervision.
The efficiency of the existing chiller plant system was about 1.86 kW/RT (kilowatt per refrigeration ton).
However, with the upgrade, improved efficiency of 0.83 kW/RT was achieved whilst the same comfort
level, relative humidity, and temperature requirements by the client were maintained. The overall savings
obtained in a year was about 2,144,362 kWh equivalent to US$231,434.00.
The hospital lighting uses the conventional ballast T8 40W 4 feet tube and T8 2 feet tube. There were
about 7,000 units of lighting for both sizes. For the lighting retrofit, the existing lighting was replaced with
a new LED lighting with a lower power rating of 10.5W for the 4 feet tube and 9W for the 2 feet tube. The
total energy savings achieved in a year was about 936,211 kWh, equivalent to a cost savings of
US$101,042.00.
Below is the summary of the EPC project:
1) Total electricity savings from chiller plant system annually: 2,144,362 kWh/year
2) Total electricity savings from LED lighting annually: 936,211 kWh/year
3) Total electricity savings from chiller plant system and LED lighting annually:
2,144,362 kWh + 936,211 kWh = 3,080,573 kWh/year
4) Total electricity cost savings:
3,080,573 kWh/year x US$0.108/kWh = US$332,702.00
5) 80% savings goes to ESCO: 80% x US$332,702 = US$266,161.50
6) Total investment cost by ESCO: US$850,000.00
7) Simple payback period: 850,000.00
266,161.50= 3.19 𝑦𝑒𝑎𝑟𝑠
8) Internal rate of return (IRR) = 26.56%
6. Road Map for Establishing the ESCO Market in Cambodia (2020–2025)
ESCOs have been promoted in developing countries through various programmes and mechanisms. The
support of international development agencies and financial institutions, as well as developing country
governments, has been particularly critical to ESCO success. However, other programmes and
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mechanisms, including domestic financial institutions, ESCO associations, utilities, and joint ventures with
multinational ESCOs, have also played a key role in some countries.
ESCO development has not started in Cambodia yet. Most of the energy efficiency projects are conducted
by in-house or general engineering contractors. To kick-start the establishment of ESCOs, a road map is
structured in three phases in the GDE guidelines for the planning of establishing ESCOs in the country.
During phase one (2020–2021), promotion and creating awareness of ESCOs are important to develop
the industry together, with stakeholders’ engagement with agencies such as the GDE, energy efficiency
equipment suppliers, Cambodia Constructors Association, Board of Engineers of Cambodia, and factory
owners. Although the major impact from energy efficiency is envisaged to be from the private sector, the
role of government institutions and government-linked companies are crucial for the successful
introduction of energy efficiency initiatives and the EPC project. The government can implement a
demonstration project and, through circulars, direct its institutions and ministries to practise energy
efficiency in its operations. With the ESCO industry in its infancy, the partnership of foreign and local
ESCOs is needed to provide experience and knowledge transfer to the local ESCOs. In addition,
registration and licensing requirements for ESCOs would improve trust and regulate the market.
In phase two (2022–2023), with a successful completion of a demonstration project, the government can
actively promote the benefits of energy efficiency projects implemented by ESCOs to the public and the
private sectors that can increase the take-up rate. The government can share the electricity savings data
obtained from the demonstration project with the local financial institution regarding the benefits of
financing EPC projects, which can be part of their portfolios soon. Lastly, in phase two, the formation of
an ESCO association can play an important role in promoting energy efficiency investments in
collaboration with government agencies, banks, and utilities companies. The ESCO association could
participate in public outreach programmes, explore the creation of new partnerships, and provide
training and capacity building for their members. They can also promote working relationships amongst
members, allowing them to collaborate on projects and to take on larger projects that require a
combination of various skill sets and financial strength. International partnerships and collaboration
amongst ESCOs and ESCO associations are also critical for information exchange and capacity building.
ESCOs in developed countries could play an advisory role in countries where they do not wish to fully
operate but may engage on a joint venture basis.
For phase three (2024–2025), the government or the agency in charge of ESCOs can prepare the
standardised guidelines and mechanism of energy performance and measurement and verification
contracts to facilitate the clients’ and financial institutions’ understanding of ESCOs and other concerns.
Tax incentives and import duty exemption for ESCOs and energy efficiency technology within a certain
period will spur the growth of the industry. With the incentives provided by the government, the
participation of local ESCOs in the industry will increase, and the government can call for EPC proposals
for government buildings to further reduce the cost of energy use.
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Table 2.1: Road Map Milestone for ESCOs with Leading and Responsible Organisations
Phase Milestone Activities Target Groups Organisations Involved Time Schedule
Phase 1A Initiation of stakeholders’ engagement Promotion and awareness Demonstration project
GDE Engineering institutions and associations Cambodia hotels, factories, and malls
2 years
Phase 1B ESCO registration and licensing requirements
GDE and Ministry of Commerce
GDE and Ministry of Commerce
2 years
Phase 1C Foreign and local ESCO partnership
GDE Foreign ESCO and engineering institutions and associations
1 year
Phase 2A Financing mechanism and engagement with local financial institutions
GDE and Ministry of Economy and Finance
Local banks and financial institutions
2 years
Phase 2B Formation of ESCO Association Cambodia
GDE and Ministry of Commerce
Engineering institutions and associations
1 year
Phase 2C Promotion of successful pilot project
GDE Engineering institutions and associations Cambodia hotels, factories, and malls
1 year
Phase 3A Government tax incentives GDE and Ministry of Economy and Finance
GDE and Ministry of Economy and Finance
2 years
Phase 3B EPC standardised guidelines
GDE *ESCO Association of Cambodia
1 year
Phase 3C Request for proposal for EPC in government buildings
GDE and Ministry of Public Works and Transport
*ESCO Association of Cambodia
1 year
* To be established. EPC = energy performance contract/contracting, ESCO = energy service company, GDE = General Department of Energy. Source: Author.
References
ASEAN Centre for Energy (ACE) (2017), ASEAN ESCO Report. Jakarta: ACE.https://aseanenergy.org/esco-
report/
Boza-Kiss, B., P. Bertoldi, and M. Economidou (2017), ‘Energy Service Companies in the EU: Status Review
and Recommendations for Further Market Development with a Focus on Energy Performance
Contracting’, JRC Science for Policy Report, Luxembourg: European Commission,
https://publications.jrc.ec.europa.eu/repository/bitstream/JRC106624/kjna28716enn.pdf.
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Ellis, J. (2010), Energy Service Companies (ESCOs) in Developing Countries. Winnipeg, Canada:
International Institute for Sustainable Development, Canada.
https://www.iisd.org/pdf/2009/bali_2_copenhagen_escos.pdf,
Hor, K. (2014), ‘EPC Development/Suitability for the Government Sector and How It Should Be
Implemented,’ Building Sector Energy Efficiency Project
(BSEEP),https://www.st.gov.my/en/contents/presentations/EPC_2014/How%20EPC%20is%20su
itable%20to%20be%20implemented.pdf.
International Energy Agency (IEA) (2018), ‘Report on Energy Services Companies (ESCOs): At the Heart of
Innovative Financing Models for Efficiency,’ https://www.iea.org/reports/energy-service-
companies-escos-2/esco-contracts.
Jensen, H.R. (2017), Energy Performance Contracting Guidebook, Building Sector Energy Efficiency
Project, Malaysia: Public Works Department.
Umar, Z. (2014), Demand Side Management (DSM), Malaysia: Energy Commission,
https://www.st.gov.my/en/contents/presentations/EPC_2014/Demand%20Side%20Manageme
nt.pdf.
World Bank Energy and Extractives Global Practice ECA Region (2019), Roadmap for the Implementation
of Energy Efficiency in Public Buildings of the Kyrgyz Republic, Washington, DC: The International
Bank for Reconstruction and Development/The World Bank Group.
http://documents.worldbank.org/curated/en/491271560400148398/pdf/Roadmap-for-the-
Implementation-of-Energy-Efficiency-in-Public-Buildings-of-the-Kyrgyz-Republic.pdf.
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Chapter 3
Energy Managers
Luk Chau Beng
1. Developing Certified Energy Managers
Implementing an energy efficiency and conservation (EEC) programme requires the commitment of all
parties starting from the government to stakeholders and the public at large. The government shall
promote awareness on policies, regulations, guidance, enforcement, and provide support to all
stakeholders, including the public, through various forms of mass media and education campaigns. The
stakeholders shall support and abide by the regulations collectively to achieve the goals and objectives of
these initiatives. Cambodia, through the General Department of Energy (GDE), Ministry of Mines and
Energy (MME), is believed to have plans of drafting and implementing new EEC regulations. Whilst waiting
for the EEC regulations to be enforced, the GDE can kickstart its intention through awareness programmes
and workshops with various stakeholders. This chapter addresses the needs, duties, and methodology of
developing energy managers to support the implementation of such regulations.
In meeting these expectations and targets of the EEC programme, a responsible energy professional
person called a ‘certified energy manager’ (CEM), who is well accepted in an energy-intensive
organisation, will be appointed to promote and manage energy utilisation efficiently through a systematic
energy management system. He will need to use his interpersonal skills to educate and increase
awareness, motivate, and create behavioural change in the organisation to adapt to the new energy
management concept. With these requirements, the CEM shall be a person proficient in management,
information skills, and conversant with technical plant processes and other matters relating to energy
management within the business entities.
1.1. Definition of certified energy managers
A CEM is a person who holds a national energy manager licence from the GDE, MME. Once the new EEC
regulations are enforced, the owner of a designated building or factory (refer to Section 6.2) shall engage
a CEM to ensure that use of energy in the energy-intensive premises are being managed efficiently. To
achieve these goals, a CEM needs to set objectives, targets, and plans to achieve such planned targets,
aside from reporting to the management of the premises and to the GDE.
The CEM needs to set up an in-house energy management committee with representation from all
departments to collectively manage and reduce energy consumption. Hence, he or she should be
technically competent and trained; possess interpersonal, execution, management and information
knowledge and skills; and is familiar with EEC practices.
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1.2. Skills and competence required of certified energy managers
A CEM clearly requires a mix of hands-on experience on technical plant process and EEC knowledge, and
interpersonal, analytical, , and managerial skills, using appropriate tools and techniques to achieve the
EEC goals. The five key components of a CEM competence (Oung, 2013) are:
1) Personal management – managing oneself of EEC behaviour and conserving the use of energy through
scheduling and prioritising actions.
2) Interpersonal management – dealing with the internal organisation and external parties (consultants
and contractors), resolving conflicts, facilitating meetings, building an energy-efficient culture,
organising resources, delegating tasks, setting business goals and evaluating performance, creating
and managing networks, etc.
3) Data information management – observing, interviewing, measuring, monitoring, and other means
of gathering energy consumption data, evaluating, modelling and processing the data, and
disseminating energy consumption performance to the management and relevant departments for
the success of the energy reduction programme.
4) Execution – planning and creating a vision for EEC, carrying out risk assessment, identifying
opportunities, followed by mobilising tools and resources to reduce energy consumption.
5) Technical competencies – establishing and following a systematic energy management programme.
This includes monitoring, measurement, documentation and reporting, plant process knowledge and
energy use, energy audit, energy-saving measures and latest energy-efficient technology.
1.3. Duties of certified energy managers
1) Meeting the regulatory requirements
The CEM is responsible for compiling the in-house documentation to comply with the regulatory
requirements of efficient energy management (EEM) of the designated premise. Figure 3.1 summarises
what the regulator (GDE) expects from a CEM. The contents of a periodical report by a CEM is shown in
section 3.2.4
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Figure 3.1: Functions of Energy Managers under the Regulations
Source: Electricity Supply Act 1990, Malaysia.
2) Managing energy use in designated premises. This includes:
• Understanding how energy resources are being used and shares of energy use by various
significant energy users;
• Determining how a change in production or process affects energy consumption; and
• Identifying the effect of future company plans and activities on energy demand and energy cost.
3) Acting as a centre for energy data information
• Providing data to the company’s management for management reviews and approving
organisation improvement plans;
• Providing information on actual energy consumption to all staff of the organisation. This will
generate awareness of their effort and achievement and, hence, will motivate staff to monitor
and track their targets.
• Installing appropriate online metering at significant energy-user locations to collect and trend
such data.
4) Monitoring energy consumption pattern
• Assessing the key performance of each significant energy user, analysing the quantity of energy
used, and identifying opportunities for improvement; and
• Communicating the energy input and deviations to the identified departments for immediate
corrective action as well as planning for long-term improvement.
5) Energising and promoting engagement from all personnel
• The CEM needs to get the buy-in from the management and participation of the whole
organisation in implementing culture change and creating a network of energy change teams to
achieve the organisation’s EEC goals.
Audit and analyse the total energy consumption or generation.
Advise in developing and implementing measures to ensure efficient management of energy at the installation.
Monitor effective implementation of measures.
Supervise the keeping of records on efficient management of energy at the installation and verify its accuracy.
Ensure the timely submission of information and reports under the regulations.
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• Educating the staff on business needs and means to reduce energy consumption.
6) Managing improvement projects, liaising with all parties to successfully implement and complete
the project.
1.4. Example of focus areas for CEMs on high-impact EEC measures in designated premises
A CEM should focus and act to manage high-impact EEC measures at the designated premises to
optimise energy use, recover waste heat, minimise energy losses, and improve operational efficiency.
• Industries
o Good combustion efficiency of fuel
o Optimisation of the usage of waste heat recovery
o Prevention of energy loss due to poor insulation, leakages, and poor heat transfer
o Use of energy-efficient equipment and proper operational control for varying demand
o Efficient use and conservation of electricity
o Substitution of energy
• Buildings
o Use of energy-efficient construction materials
o Shading of heat from sunlight into the building.
o Use of efficient heating, ventilation, and air conditioning (HVAC) equipment with proper control
of room temperature
o Use of energy-efficient office equipment and fittings, such as lighting with proper operational
control
2. Registration and Licensing of Certified Energy Managers
Cambodia is implementing EEC measures in designated premises through the new EEC regulations. The
objectives of these regulations are to ensure that energy is efficiently and effectively used, the specific
energy consumption and energy costs for designated premises are reduced, the competitiveness of the
economy is increased, the dependence on imported fuel is decreased, and the natural environment of
the country is protected.
The development and implementation of the new EEC regulations have been suggested to be under the
purview of the Department of Energy Technique and Energy Business Policy (DoET&EBP), a department
under the GDE. In the National Efficiency Policy, the Ministry of Industry, Mines and Energy (currently
MME) declared its willingness to reduce energy demand by 20% and national carbon dioxide emission by
3 million tons by 2035 (MIME, 2013).
In the National Policy, Strategy and Action Plan on Energy Efficiency in Cambodia (MIME, 2013), an
estimated saving potential in the industry sector of 20% (garment industry) up to 70% (brick factories)
and in the commercial building sector of 20% to 30% is achievable. This can be achieved through (i) regular
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training to create awareness and change in people’s behaviour in the use of energy; (ii) awareness on the
substantial amount of savings that can be achieved in energy and money in their premises; (iii) identifying
operational and equipment inefficiency and carrying out regular maintenance, adjustment, or
replacement of inefficient equipment; and (iv) use of energy-efficient building materials and passive
design principles in buildings.
Amongst the major energy-consuming industries are the textile sector, followed by clay brick fabrication
for building construction, rice mills for processing paddy into polished rice, rubber production, and the
food sector with particular emphasis on the fabrication office for refrigeration. The energy-consuming
entities of the commercial sector are offices, hotels, retail stores, education, industrial, and public
buildings.
The new EEC regulations shall include a well-defined registration of designated premises based on energy
usage threshold values over a consecutive period (e.g. over 2 consecutive years), qualifications for
national certification of CEMs, mandatory training, role and responsibilities of CEMs, renewal process for
CEMs, appointment of CEMs in the designated premises, systematic and progressive implementation of
energy management at the designated premises, and reporting of CEMs to the GDE.
2.1. Establishment of a CEM advisory committee
In setting up the registration and licensing requirements for CEMs, a CEM advisory committee is first set
up to formulate the requirements for the qualifications and registration of CEMs, examination syllabus,
scheme of the examination, and registration and licensing of CEMs. The functions of the CEM advisory
committee consist of the following:
1) Set up the mandatory qualifications for the application and registration of a candidate to the national
level certification for energy managers.
2) Define the procedure and scheme of conduct of the examination.
3) Appoint the committee who will draft the national energy manager certification syllabus The CEM
advisory committee shall review said syllabus and endorse it before sending to the Board of
Examinations for approval.
4) Review feedback from the industries, the candidates, and the public from time to time regarding the
syllabus and procedure of the examination; and recommend measures for the endorsement by the
Board of Examination.
5) Appoint the controller of examination and other approved officers such as invigilators and panel
evaluators responsible for the conduct of the examination. Allow the controller of examination to
deal directly with the approved panel of examiners for conducting the examination, and to supervise
the secrecy and confidentiality of the printing and distribution of the questions.
6) Appoint the panel of examiners for paper setting, criteria of evaluation of papers, and moderation.
7) Appoint a vigilance officer to ensure that the examinations are conducted fairly and in a prescribed
manner per the rules.
8) Approve the examination results and forward its recommendation for the announcement of the
results.
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9) Invite experts and other competent persons to advise the board on matters pertaining to the
syllabus, conduct, and scheme of examination.
The CEM advisory committee is recommended to be set up under the Board of Examination. The
committee consists of the
• Director General of the GDE, MME as the chair of the CEM advisory committee
• Director of the DoET&EBP, GDE as the Secretary
o He submits a list of organisations, deemed to have influence on EEC activities, to the Board of
Examinations for approval to be appointed as members of the committee.
o Upon the approval by the Board, he then writes to and request each head of these organisations
to nominate an EEC expert to be part of the committee.
o Organisations may include:
▪ Primary members consisting of ministries and governmental agencies such as the
DoET&EBP under the DGE, Electricite du Cambodge (EDC), Electricity Authority of
Cambodia, and other relevant ministries such as the Ministry of Urban Planning and
Construction, the Ministry of Labour and Vocational Training, etc.;
▪ Manufacturing associations (garment, breweries, rice millers, food industries, brick,
chemicals, etc.);
▪ Commercial stakeholders (hotels, malls, hospitals, and other commercial buildings);
▪ Professional institutions (Board of Engineers Cambodia, etc.);
▪ Institutions of higher learning (universities, technical college, and polytechnics).
2.2. National accredited qualification and certification for energy managers
Figure 3.2 shows the activities needed to be set up in developing and implementing the new national
accredited qualification and certification process for energy managers.
25
Figure 3.2: Overview of Implementation of Energy Managers’ Programme
CEM = certified energy manager, GDE = General Department of Energy. Source: Author.
1) Minimum qualifications
a) Minimum educational background (e.g. a first degree in engineering, science, and architecture or
a higher vocational certificate in engineering)
b) Minimum working experience in the field of energy management (e.g. 2 years). The experience
may include the use of energy in operation and maintenance, planning, and energy auditing. The
management of the designated premises must provide evidence of the applicant’s experience in
energy management.
c) Completion of the mandatory energy manager training, as detailed in section 3.3.1, that is
accredited by the DoET&EBP or the GDE.
2) Energy manager’s certification syllabus
The suggested list of national certification syllabus for an energy manager covers three sections (Figure
3.3): section 1 covers the basic aspect of regulations, energy management, and energy audit; section 2
covers the fundamentals of electrical and thermal energy; and section 3, a specialisation field, covers
energy management in equipment and system using large energy and its savings potential.
Figure 3.3: Sample Syllabus for Energy Manager Certification Course
HVAC = heating, ventilation, and air conditioning. Source: Author.
Activities
CEM Advisory Committee
Responsible AgencyDepartment of Energy
Technique & Energy Business Policy, GDE
Professional bodies
Industrial and building stakeholders
QualificationsCertification
syllabusMandatory
trainingCertification
process
Registration and licensing
of CEM
Continuous professional development
Institutions of higher
learning
Related ministries and
agencies
• Section 1: General Aspect of Energy
Management and Energy Audit
• Energy scenario
• Energy policy and legislation
• Energy pricing
• Efficient energy management
• Energy audit
• Energy reporting and presentation
• Measurement and monitoring
• Energy performance target
• Section 2: Fundamentals of Electrical
Thermal System
• Electricity, heat, fluid, fuel, and combustion
Section 3: Energy Efficiency Potential
• Electric motors, demand controls including
variable speed control
• Compressed air, fans and blower system
• HVAC, refrigeration systems, and cooling tower
• Electric heating system
• Lighting systems
• Boilers, furnaces, and heating systems
• Heat exchangers and heat recovery equipment
• Pumps and pumping system
• Steam systems
• Insulation and refractories
• Cogeneration and waste heat recovery system
• New energy-efficient solutions and
technologies
26
3) The certification process
Figure 3.4 shows the process for the application for CEM certification.
The examination will be conducted according to the approved Energy Manager Certification Syllabus as
in section 3.2.2(2). The examination may include a written test with descriptive or numerical questions,
an oral assessment, and a project based on EEC exercise carried out at the designated premises by the
candidate himself. All candidates are required to achieve the minimum passing marks in all three parts.
The controller of examination manages the examination with the assistance of other officers such as
invigilators, a panel of evaluators, and a vigilance officer. After the examination, he then compiles all the
marks from the panel of evaluators and sends these to the CEM advisory committee for endorsement.
The announcement of the results shall be carried out after the final approval by the Board of
Examinations. A CEM licence shall then be issued by the GDE, duly signed by the Board of Examinations.
Figure 3.4: Process of Certification of Energy Managers
CEM = certified energy manager, DoET&EBP = Department of Energy Technique and Energy Business Policy, GDE = General Department of Energy. Source: Author.
2.3. Licensing and renewal of certified energy managers
After the GDE announces the results, candidates who passed the examination shall apply for a CEM
licence. The GDE shall then issue such licence, to be renewed yearly upon the CEM’s submission of the
application for renewal, payment of renewal fees, and continuous professional development (CPD)
records as required by the regulation.
START
Candidate applies
online to sit for
Energy Manager
certification through
GDE website
DoET&EBP processes
the application
CEM Advisory
Committee endorsed
results
DoET&EBP issues
invitation for the
examination
Meets
qualifications?
PASS?
Evaluation of project
paper, answer book,
oral assessment
Candidate submits
project paper and sits
for both oral and
written tests
Issuance of CEM
license by DGE
DoET&EBP
informs all
candidates on the
results
Board of
Examination
approved results
End
Yes
No
Yes
Candidate to meet
requirement
No
27
2.4. Content of energy management report required of an appointed CEM2
The CEM shall monitor and report on the efficient energy management (EEM) semi-annually to the
DoET&EBP. The report shall include the following:
1) Basic information on the business activities of the designated premises, EEM policies and objectives,
and EEM committee organisation chart;
2) Types and description of energy-consuming system;
3) Baseline data for 6 consecutive months before the implementation of the EEM, presented in table
and graphical format on the type, quantity, unit of measure of fuel or energy commodity used, and
the quantity and unit of measures of each intended output/production, together with the calculated
specific energy consumption;
4) Current trending similar to baseline data reporting for the next 6 consecutive months after EEM
implementation. In addition, a report on energy consumption patterns and energy distribution
breakdown shall be presented in line and pie charts, respectively. Finally, a comparison, with
comments on the reasons, of the percentage decrease or increase in energy consumption and
specific energy consumption of the designated premises.
5) List and status, in table form, of all EEM activities and projects being implemented or in progress,
cancelled, or rejected in the designated premises; if the proposed activities are being cancelled or
rejected, state the reason for rejection.
6) Summary of savings from EEM activities and projects in table form, along with the baseline
measurement. Current consumption, percentage of savings (estimate and actual), and measuring
tools. The current consumption savings achieved must be reported up to a maximum of 1 year to
ensure that the designated premise keeps track of EEM performance.
7) New EEM activities and/or projects to be implemented with a brief description, estimated energy
and cost savings, investment costs, and return benefits.
2.5. Role of the General Department of Energy
The successful implementation of the CEM programme lies in the effective development of CEM
requirements in new EEC regulations, awareness and promotion, and implementation and enforcement
of the regulations. The role of the GDE is summarised as follows:
1) Assign the DoET&EBP, under the GDE, to be responsible for setting up the new EEC regulations. The
Economic Research Institute for ASEAN and East Asia (ERIA) shall be pleased to support the GDE in
setting up the EEC regulations.
2) Appoint the CEM advisory committee to set up the various requirements for the registration and
licensing of a CEM under the new EEC regulations. The requirements for CEM includes (i) minimum
qualifications; (ii) certification syllabus; (iii) certification process; (iv) registration, licensing, and
renewal; (v) penalty and appeal; and (vi) defined designated premises.
3) Submit the EEC regulations for the approval of the Minister of Mines and Energy.
4) To launch the CEM scheme, generate awareness to the occupants of the designated premises,
industries and building associations, government agencies, local institutions of higher learning, and
professional bodies.
2 Electricity Supply Act 1990, Malaysia. Efficient Management of Electrical Energy Reg. 2008 [P.U. (A) 444].
28
5) Invite international organisations with EEC expertise, such as the Energy Conservation Center, Japan
(ECCJ), ASEAN–Japan Energy Efficiency Partnership (AJEEP), Energy Management Action Network
(EMAK), United Nations Industrial Development Organization (UNIDO), to assist in setting up the
mandatory training for CEMs.
6) Invite local energy service providers and local institutions of higher learning to the CEM mandatory
training to build their capacity as future local trainer providers.
7) Approve and accredit CEM training courses.
8) Enforce EEC regulations
• Registration, licensing, and renewal of CEM; and
• Registration of the designated premises.
9) Receive, review, comment, and communicate regarding the CEM periodical report.
10) Make information on EEC activities and achievements available to the public and the Royal
Government of Cambodia.
3. Certified Training Courses
The main barriers towards realising the full potential of the EEC are lack of awareness by industry
managers and policymakers as well as the lack of widespread education and training on energy
management and conservation at all levels of the organisation. To successfully manage EEC at the
designated premises, these barriers must first be overcome, together with a change in organisational
behaviour towards energy conservation. This success will eventually result in sustainable energy
development in Cambodia.
Effective training requires various flexible approaches, including project-based learning, case studies,
interactive programmes, quizzes, etc. In many cases, teaching quality and learning experiences are
observed to be higher when the trainer modifies and refines the training materials provided based on his
or her experience on the subject. Well-experienced and specialised field experts on the technical,
management, and commercial aspects are required. Hence, the DoET&EBP would benefit to use this
opportunity to engage the assistance of international EEC experts from international organisations such
as the ECCJ, AJEEP, EMAK, and UNIDO in identifying the potential gaps, and provide the necessary training
and capacity building during this initial stage.
At this stage, the DoET&EBP should also identify and invite EEC professionals from local institutions of
higher learning and professional bodies to be prepared as future local trainers under the guidance of
these foreign EEC experts. Once they have successfully completed their course, they can set up their own
company, develop their own course materials based on the GDE-approved syllabus, and apply to the
DoET&EBP to be a licensed training provider.
Training under this section refers to the mandatory training for energy managers as part of the
requirements for registration and the mandatory CPD training for renewal of their licence.
29
3.1. Mandatory energy manager training
The mandatory energy manager course is an approved course based on the approved syllabus (see para
3.2.2 [2]) and conducted by a training provider approved by the GDE. This course will provide the
knowledge and skills required by the CEM to execute his duties competently and effectively.
This mandatory training aims to:
• Introduce the principles of energy management with fundamental and specialised knowledge
in EEC.
• Improve measurement, verification, and analytical skills.
• Promote investments in energy savings through energy efficiency measures and technologies.
• Lead to reduction in specific energy consumption.
At the end of the mandatory course, participants will be assessed and required to pass all three modes of
assessment: (i) a written examination; (ii) submission of an energy audit carried out by the participant at
his site covering the assessment, analysis, and recommendation on energy-saving measures and
investment appraisal; and (c) an oral interview before a certificate of achievement is issued. Candidates
can use this certificate of achievement to apply for their registration as CEM.
3.2. Mandatory continuous professional development
Continuous professional development (CPD) refers to the accumulated hours of training and other EEC
activities, which are a prerequisite for the renewal of the CEM licence. The CPD provides CEMs an
opportunity to continuously update their skills and knowledge on the current EEC methodology, best
practices, efficient technologies, and specialised EEC equipment and system optimisation.
Other activities that form part of the CPD include participating in drafting EEC codes and standards and
best practice guidelines, making presentations to share knowledge and experience, and attending EEC-
related postgraduate studies.
CPD programmes can be conducted through courses, forums, workshops, and seminars. All CPD courses
must be approved with accredited hours by the DoET&EBP. The approved reference code must also be
stated on the training providers’ advertisement flyers and certificates.
Examples of training organisers are the GDE, energy manager associations, engineering professional
bodies, energy service companies (ESCOs), industry and building associations, and other training
providers approved by the GDE.
4. Setting Up the Association of Energy Managers
The Association of Energy Managers is a non-governmental and non-profit organisation set up amongst
CEMs working in designated premises and ESCOs.
An example of the vision of such association is to develop the professionalism, trustworthiness, and high
integrity of CEMs to be recognised nationally and regionally. Its mission shall play an important role in the
effective execution of government EEC policies and programmes to achieve a progressive and sustainable
Cambodia.
30
The Government of Cambodia should motivate, encourage, and assist the energy managers’ group in
setting up such association. Members may comprise CEMs, trainee energy managers, and other
stakeholders of local institutions of higher learning and owners of designated premises.
4.1. Objectives of the Association of Energy Managers
The Association of Energy Managers aims to provide CEMs a platform to network, share experiences
amongst its members, create a strong working relationship between government regulators and the
owners of designated premises, and help the government achieve its EEC goals. Other objectives include
• ensuring the welfare of its members;
• promoting a healthy competition amongst members of the association through professional
services, ethics, and integrity;
• providing professional input and feedback to the regulator about the national planning and
execution of government EEC policies, initiatives, and programmes;
• improving the competency, skills, and best EEC practices of its members to develop their business
and career path potentials as well as to increase their competitiveness;
• providing awareness on campaigns, financial incentives, or grants to implement energy-efficient
solutions and energy auditing through association portals and emails;
• guiding and assisting members deal with the regulators and relevant government agencies.
4.2. Activities of the Association of Energy Managers
• Collaboration, cooperation, and networking with the DoET&EBP by
o obtaining and sharing the latest information on any new policies, guidelines, initiatives,
activities, and other information to members;
o jointly organising EEC events such as town halls, forums, and conferences to provide
members an opportunity to dialogue and network with the regulator to clarify matters and
gain a better understanding of government initiatives and expectations;
o assisting the government achieve the national EEC goals by disseminating important EEC-
related information and motivating owners of designated premises; and
o bringing up matters faced by the members and discussing with the regulator to ensure
smooth implementation of EEC activities and protection of members’ welfare.
• Organising activities that enhance the competency, skills, knowledge, and competitiveness of energy
managers such as
o training, talks, conferences, and knowledge sharing;
o awareness on latest best practices and efficient technology;
o standard writing, study tours, and visits relating to EEC;
o working groups amongst association members in carrying out knowledge exchanges, advising
members in dealing with authorities; and
o CPD training programmes for CEMs to renew their licence.
31
5. Road Map for Developing Energy Managers (2020–2025)
Cambodia has yet to draft EEC regulations. Hence, the GDE needs to exert more effort, commit, provide
leadership, and deploy resources particularly for the new EEC regulations, which include CEM registration
and licensing. Accordingly, the execution of the road map is planned in three phases.
Phase 1 (2020–2021): Setting up the regulations for registration and licensing of energy managers
• The GDE to appoint the DoET&EBP to be responsible for setting up, implementing, and enforcing the
new EEC regulations (2020)
• Government to launch and make public the intents of EEC initiatives (2020)
• Form the CEM advisory committee to develop mandatory criteria, such as the minimum qualifications
for registration, certification, and licensing processes; functions and responsibilities of a CEM;
requirements for designated premises; reporting and efficient energy management planning;
penalties and appeal to be inserted into the EEC regulations (2020)
• Appoint a working committee to draft the examination syllabus (2020)
• Appoint a working committee to draft the EEC regulations (2020)
• The GDE to approve the certification examination syllabus for CEMs (early 2021)
• The minister to approve the EEC regulations (mid-2022).
Phase 2 (2021–2023): Awareness training, mandatory energy managers’ training, and developing
examination questions
• Start developing the mandatory energy managers’ training with assistance from international EEC
organisation experts (e.g. ECCJ, AJEEP, UNIDO, EMAK, etc.) (mid 2021)
• Conduct the first mandatory energy managers’ training with assistance from international EEC
organisation experts (e.g. ECCJ, AJEEP, UNIDO, EMAK etc.) (end 2021)
• CEM advisory committee to appoint the panel of examiners and start preparing questions (2022)
• Establish examination procedures (2022)
• The GDE to approve local trainers to conduct the mandatory energy managers’ training (2023)
Phase 3 (2024–2025): Registration and licensing
• The CEM advisory committee to appoint the controller of examination and vigilance officer to
organise and conduct the energy managers’ examination (2024)
• Controller of examination to appoint invigilator and support staff to conduct the examination (2024)
• Registration of energy managers (2024)
• Conduct of first energy managers’ examination (2024)
• Licensing of first CEMs (2024)
• Conduct of first CPD training courses (2025)
Table 3.1 shows the project milestones with leading and responsible organisations.
32
Table 3.1: Road Map Milestone for Energy Managers with Leading and Responsible Organisations
EEC = energy efficiency and conservation, DoET&EBP = Department of Energy Technique and Energy Business Policy, GDE = General Department of Energy. Source: Author.
References
Electricity Supply Act of 1990, Efficient Management of Electrical Energy Regulations 2008 [P.U. (A) 444],
Malaysia.
Energy Conservation Act 2012 (Act 11 of 2012), Energy Conservation (Energy Management Practices)
Regulations 2013, Singapore, https://sso.agc.gov.sg/SL/ECA2012-S246-2013.
EU Energy Initiative Partnership Dialogue Facility (EUEI PDF) (2013), National Policy, Strategy and Action
Plan on Energy Efficiency in Cambodia, Phnom Penh: Ministry of Industry, Mines and Energy
(MIME), http://www.euei-
pdf.org/sites/default/files/field_publication_file/EUEI_PDF_Cambodia_Energy_Efficiency_May2
013_EN.pdf (accessed 15 September 2019)
Oung, K. (2013), Energy Management in Business: The Manager’s Guide to Maximising and Sustaining
Energy Reduction. New York: Gower Publishing Limited.
Shapiro, I.M. (2016), Energy Audits and Improvement for Commercial Buildings. New York: John Wiley &
Sons. Inc.
The Energy Conservation Promotion Act of 1992, B.E 2325, Thailand.
The Energy Conservation Act of 2001, No. 52 of 2001, India.
Milestone Activities Leading
Organisation
Involved
Organisations
Schedule
Phase 1 ✓ Government to launch EEC initiatives;
Form a task force (including Examination
Advisory Committee) to draft Act, regulations,
and examination syllabus
✓ EEC Act and energy managers’ regulations
✓ Establish syllabus for energy managers
✓ Enactment of EEC Act and its regulations
- GDE
- Professional
institutions
- Industrial and
building associations
- Institutions of higher
learning and
ministries
Start
3 years
1 year
1 year
Phase 2 ✓ Start training of energy managers with
international energy efficiency organisations
✓ Appoint panel of examiners and prepare
examination questions
✓ Establish examination procedures
✓ Approve local trainers for mandatory
courses for energy managers
- GDE - International
organisations with
expertise in energy
efficiency, experts,
and stakeholders
- Appointed panel
- Task force
- Local experts on
energy efficiency
1–3 years
1–2 years
1–2 years
1–2 years
Phase 3 ✓ Set up new EEC regulatory department to
manage all EEC matters
✓ Appoint controller of examination who then
appoints invigilators and support staff
✓ First examination for energy managers
✓ Registration of energy managers
✓ Continuous professional development
- GDE - GDE
- Examination
Advisory Committee
- EEC regulator
department
- Training organisers
1 year
½ year
½ year
½ year
½ year
33
Chapter 4
Standards and Labelling
Yau Chau Fong
1. Introduction
Organisations put in place standards to have a basis for making a judgement and a commonly agreed way
of doing things within or beyond the organisations. Standards provide requirements, specifications,
guidelines, or characteristics that can be used consistently to ensure that materials, products, processes,
and services are fit for their purpose.
Labelling is a way of identifying products and/or services; it gives the user a way of recognising such
products and/or services and differentiate these via a set of criteria or set standards.
1.1. Energy labelling
Energy efficiency labels are informative labels affixed to manufactured products indicating a product's
energy performance. They provide consumers with the information necessary to make a knowledgeable
purchase decision. Some countries mandate that energy labels be displayed on certain electrical products
for sale.
Energy rating and labelling have been a cornerstone in the market transformation of household appliances
towards more energy-efficient models. They have been successfully applied worldwide in Europe, the
United States, Japan, Australia, Thailand, etc. for more than a decade and have resulted in significant
improvements in the energy efficiency of the technologies.
1.2. Minimum energy performance standards
A Minimum energy performance standard (MEPS) provides performance requirements for energy-related
products, specifically the minimum amount of energy to be consumed in performing a product’s task.
Energy performance improvements in consumer products are an essential element in any government
initiatives and objectives for energy efficiency and climate change mitigation programmes. Generally, a
MEPS is implemented by a government energy efficiency body. The initial stages of a MEPS are voluntary
and amendments are then made to the existing act or directive to regulate products, thus, making MEPS
mandatory to the respective country. A MEPS generally requires standards to be developed and agreed,
followed by setting up of test procedures that provides the measurement of the standards set.
If MEPS were to be made mandatory, only the electrical products that are listed in energy labelling,
meeting the requirements of MEPS, are allowed to be offered for sale or used for commercial purposes.
Therefore, MEPS and energy labelling are recommended to be used as part of the energy efficiency
strategies to improve energy performance in Cambodia.
MEPS generally requires the use of a particular test procedure that specifies how performance is
measured. With the MEPS in place, an energy labelling system shall be used, and registration of the
equipment shall be done based on the labelling categories or ratings system. This would set an energy
benchmark to the equipment used and purchased by end users.
34
Five member states of the Association of Southeast Asian Nations (ASEAN) – Malaysia, the Philippines,
Singapore, Thailand, and Viet Nam – have adopted MEPS and labelling schemes. Some countries that have
implemented energy labelling and MEPS are listed in Table 4.1.
1.3. Current scenario in Cambodia
Based on the numerous workshops conducted by the Economic Research Institute for ASEAN and East
Asia (ERIA) with the Ministry of Mines and Energy (MME), there are already some initiatives to implement
MEPS and energy labelling for certain electrical appliances (refrigerator and air conditioning) as a pilot
project. The project is now in the final stage of issuance of the draft sub-decree. However, although MEPS
and energy labelling are already in progress, no specific road map and finalised initiatives for the entire
household equipment are yet in place.
As part of the energy efficiency measures, the electrical equipment used is recommended to comply with
the MEPS which, in turn, will reduce the overall power consumption of the said premises. With MEPS in
place, an energy labelling system shall be used, and registration of the equipment shall be done based on
the labelling categories. This would set an energy benchmark to the equipment. Therefore, any equipment
that meets all the requirements of efficient electricity use shall be affixed an efficiency rating label in such
form and manner as may be determined by the MME.
The following sections will provide the current gaps and future proposed road map in implementing
MEPS and energy labelling in Cambodia.
Table 4.1: List of Countries that Adopted Energy Labelling
Country Programme Name Implementing Agency Participation Mode
Malaysia Energy Efficiency Criteria for Material and Electrical Equipment to Qualify for the Minimum Energy Performance Standards Star Rating
Suruhanjaya Tenaga (Energy Commission of Malaysia)
Mandatory
China China Energy Label The China Energy Label Center; part of the China National Institution of Standardization
Mandatory
Japan Uniform Energy Saving Label Ministry of Economy, Trade and Industry, Japan (METI)
Mandatory
European Union (EU)
EU Energy Label National bodies of EU member countries
Mandatory
United States of America (USA)
Energy Guide USA Federal Trade Commission Mandatory
Indonesia Energy Efficiency Labelling Ministry of Energy and Mineral Resources
Mandatory/Voluntary
Singapore Mandatory Energy Labelling Scheme
National Environment Agency, Singapore
Mandatory
Viet Nam Energy Label Ministry of Industry and Trade, Vietnam
Mandatory/Voluntary
Philippines Philippine Appliance Energy Standards and Labelling Programme
Department of Energy, Philippines Mandatory
Thailand Energy Efficiency Label No. 5 Electricity Generating Authority of Thailand
Voluntary
Source: Author’s research and compilation.
35
2. Identification of Relevant Institutions
Whilst the focus is to develop MEPS requirements, it is also essential to identify the new or existing local
institutions and potential agencies to be appointed to carry out MEPS activities.
These include standard-writing organisations (SWOs) for electrical equipment labelling standards, the
testing bodies for testing of compliance, and certification bodies for certificates of approval.
2.1. Standard-writing organisation
A standard-writing organisation (SWO), standard-developing organisation, or standard-setting
organisation is a firm or entity whose primary activities are developing, coordinating, promulgating,
revising, amending, reissuing, interpreting, or otherwise producing technical standards on energy-
efficient equipment intended to address the needs of a group of affected adopters.
In most countries, most standards are voluntary; they are offered for adoption by people or industry
without the mandate of law. Some standards become mandatory when they are adopted by regulators
as legal requirements in particular domains.
2.2. Testing bodies
Testing bodies independently verify compliance of products with energy efficiency standards and
regulations. They provide an independent assurance that tests are done according to stated specifications
and test methods in the standards produced by the SWOs. Testing bodies also enhance customers’
acceptance and confidence on the quality, reliability, and safety of products. They help minimise the risk
of consumers buying an inferior product not in compliance with energy efficiency standards or
requirements.
2.3. Certification bodies
Certification bodies are independent bodies responsible for the assessment and accreditation of certain
organisations. In our context, they are the SWOs and testing bodies for energy labelling and standards.
Certification bodies provide conformity certificates to organisations for their various management
systems, individual as well as product manufacturers and service providers. Accreditation is the formal
recognition by an independent body, generally known as an accreditation body, that a certified body
operates according to international standards.
2.4. Setting up of institutions
In the context of energy labelling and standards, the above institutions should work togther to ensure the
success of the implementation of labelling and standards (Figure 4.1). The SWOs for electrical equipment
labelling standards will produce the required MEPS, which incorporate testing requirements or
conformance standards. The testing bodies will then test the respective MEPS-complied products
accordingly. The certification bodies will assess the standards made and requirements of testing bodies
to ensure both bodies comply with the standards.
36
Figure 4.1: Interrelation between Institutions
Source: Author.
3. Selection of Targeted Appliances
A wide range of electrical appliances are produced in the market for consumers. Targeted appliances to
be selected for labelling – such as lighting, refrigerator, air conditioning, fan, television, water heater,
washing machine, and others – shall be reviewed in terms of their market availability, distribution, and
power consumption contributions to the entire energy utilisation. Hence, the selection of the targeted
appliances is suggested to be done in two stages: stage 1 for residential appliances and stage 2 for
commercial/industrial appliances and equipment.
The priority for labelling should be given to residential appliances. This is because the preliminary focus is
to reach a wider range of, and more common, appliances used in the market compared to commercial
and industrial equipment which are more specific and unique. Another consideration is the market share
of the product selected for energy labelling and standards to achieve a greater impact in energy savings.
Table 4.2 outlines some countries’ appliances with MEPS and energy labelling and their status.
3.1. Selection of pilot project appliance
The MME, through the ASEAN SHINE Programme, initiated a pilot project to set up the MEPS requirements
for air-conditioning system. A draft Sub-decree on Energy Efficiency Standard and Labelling for Air
Conditioners is in place and approval is being sought.
One or two pilot projects are recommended to be chosen to formulate the necessary MEPS and energy
labelling. Besides the air-conditioning system, we are also recommending that lamps be chosen as well.
This is in line with the countries that had adopted MEPS and energy labelling. Lamps are also one of the
most-used electrical appliances consumed in typical homes with potential for local manufacturing.
After choosing the pilot project, the following steps are recommended to be adopted in producing a good
MEPS:
1) Select a MEPS rating reference. 2) Choose a reference from amongst ASEAN countries to be adopted as guide. 3) Form a working group for MEPS and energy label rating, which includes all stakeholders in the
country. 4) Draft the MEPS requirements.
Certification Bodies
Standard-Writing Bodies
Testing Bodies
37
Table 4.2: Selected Countries’ Appliances with MEPS and Energy Labelling and their Status
Country Indonesia Thailand Malaysia Singapore Philippines Viet Nam
United States
Japan European Union
China Lao PDR
Myanmar Brunei Cambodia
Air-conditioning system
YES YES YES YES YES YES YES YES YES YES X X X X
Fan YES YES YES X X YES YES X YES YES X X X X
Refrigerator YES YES YES YES YES YES YES YES YES YES X X X X
Lamp YES YES YES YES YES YES YES YES YES YES X X X X
Television YES YES YES YES X YES YES YES YES YES X X X X
Washing machine YES YES YES X X YES X X X YES X X X X
Source: Author, based on respective countries’ official websites, as follows: Indonesia – http://www.ebtke.esdm.go.id/ Thailand – http://labelno5.egat.co.th/ Malaysia – https://www.st.gov.my/web/consumer/details/7/2 Singapore – https://www.nea.gov.sg/ Philippines – https://www.doe.gov.ph/pelsp–ig Viet Nam – http://www.moit.gov.vn/ United States – https://www.ftc.gov/news-events/media-resources/tools-consumers/energyguide-labels Japan – https://meti.go.jp/english/policy/energy_environment/energy_efficiency/index.html European Union – https://ec.europa.eu/environment/ecolabel/competent-bodies.html China – https://en.cnis.ac.cn/
38
3.2. Common Requirements for MEPS
A few new common criteria are observed and used in setting up MEPS, as follows.
1) Scope
The standards proposed shall define the products that shall be included in the standards.
Inclusion or exclusion of products could be based on the product type, power rating, or usage
type.
2) Normative standard
The standards set shall have a set of normative reference standards to refer to any existing
performance standards, international standards such as the International Electrotechnical
Commission (IEC), American Society of Heating Refrigerating and Air-Conditioning of Engineers,
etc. and reference requirement for the condition, testing method, and performance.
3) Terms and conditions
The specific terms and conditions shall be identified for the appliances. These include the
following:
a) The standards that will depict the parameters to be used to determine the appliance’s
performance, such as:
• Fan : Coefficient of performance (COP)
• Refrigerator : Energy efficiency factor (EEF)
• Air conditioner : Energy efficiency ratio (EER)
• Television : Energy efficiency factor (EEF)
• Lamp : Efficacy
b) Minimum energy performance standards – the required minimum level of energy will be
defined.
Star rating requirements – A range of ratings and requirements to define the level of
compliance of the energy performance. The common method will be to categorise the
star rating and range, such as star rating 1 to 5. Some appliances such as lamps do not
require any star rating.
3.3. Choosing a reference from an ASEAN country to adopt as guide
Since some ASEAN countries – such as Malaysia, the Philippines, Singapore, Thailand, and Viet Nam – have
energy labelling and MEPS requirements in place, Cambodia can refer to these countries in terms of the
requirements because of regional suitability, environmental conditions, and availability of similar regional
products.
39
3.4. Formation of working group for MEPS finalisation
With the above in place, a working group shall be set up to draft the MEPS for a particular appliance. As
far as practicable, the working group should involve relevant stakeholders such as the regulators,
suppliers, testing bodies, end users, designers, distributors, manufacturers, and others involved in the
products.
3.5. Typical standards-writing procedure
After the working group is formed, it would then work on the writing of standards. The publication of
standards is the result of an agreement between all stakeholders.
The preparation of the typical new standards involves the following stages: preliminary, proposal,
preparatory, enquiry/review, approval, and publication.
The preliminary stage normally consists of projects envisaged for the future but not yet ripe for immediate
development – or preliminary work – such as better definition of a project for new work, data collection,
or round-robin tests necessary to develop standards, which are not part of the standardisation process.
The preliminary stage is applied for work items where no target dates can be established. This stage can
be used to elaborate a new work item proposal and develop an initial draft. These work items are subject
to approval according to normal procedures before progressing to the preparatory stage.
The next stage is the proposal stage whereby the preliminary outline of the standard is circulated to
stakeholders for feedback before deciding whether to proceed.
During the preparatory phase, a working draft is prepared. The preparatory stage ends when a working
draft is available for circulation to the working group members. The committee may also decide to publish
the final working draft to respond to particular market needs.
During the enquiry/review stage, the working draft standards are made available and published for
comments and/or amendments. If these are relevant, a final draft is then produced.
The final draft is discussed amongst the working group members; if approved, it will be sent for final draft
publication or subsequent further approval by higher management.
4. Testing Bodies
Another important element of MEPS and energy labelling is the testing facilities available to carry out the
product appliance compliance test to MEPS. We have reviewed the existing lab facilities in Cambodia,
which could carry out various tests to comply with the requirements. We have also reviewed the current
international and regional labs to assist with the testing to conform with the standards set. Currently, no
accredited testing labs in Cambodia exist. There is only an electrical product safety certification scheme
by third-party testing.
The Institute of Standards of Cambodia (ISC) via its ISC Product Certification Scheme provides rules for a
third-party certification system of conformity assessment through testing and assessment of the factory
quality management system. The scheme is imperative for products covered under mandatory standards.
40
Manufacturers are required to apply for a product registration licence to affix the ISC mark on products.
The products are compliant with Cambodian standards and/or those of the International Electrotechnical
Commission (IEC). Foreign manufacturers, through a local representative, also need to sign an agreement
to use the ISC mark.
Because of the unavailability of a certified test laboratory in Cambodia, the country could, for a start,
collaborate with some of the regional test laboratories to carry out the tests accordingly. Numerous
internationally accredited test laboratories are available and registered under the ASEAN Secretariat.
These are listed as testing laboratories and certification bodies under the ASEAN Sectoral Mutual
Recognition Agreement (MRA) for Electrical and Electronic Equipment.
Whilst no existing laboratories or labs are available for immediate acceptance of MEPS and required
energy labelling, Cambodia should also develop its own testing bodies and labs. Following are the typical
procedures in obtaining test lab competency and accreditation internationally.
4.1. Designation and set-up
A testing laboratory is to be identified and designated as the testing body for the country. The testing lab
shall have the following competencies:
1) Accreditation to ISO/IEC 17025 (General requirements for the competence of testing and calibration
laboratories) or ISO/IEC 17025:2005, which specifies the general requirements for the competence to
carry out tests and/or calibrations, including sampling. It covers testing and calibration performed
using standard methods, non-standard methods, and laboratory-developed methods.
2) Participating in the IECEE CB Scheme (IEC System of Conformity Assessment Schemes for
Electrotechnical Equipment and Components) Certification Body Scheme. The IECEE CB programme is
a globally standardised approach to test and verify energy efficiency for electrical and electronic
equipment, based on IEC International Standards.
It aims to prevent duplication of testing, reduce costs, and support global trade in a timely manner. The
IECEE CB programme will provide proof of compliance to IEC International Standards in terms of energy
efficiency in general and, more particularly, in energy performance, and energy consumption.
The testing laboratory then obtains the certificate of designation from the designated body.
4.2. Nomination and listing in ASEAN
To ensure that the testing body is also in the ASEAN-designated testing lab list, the country shall
nominate the testing lab to the respective committee, JSC EEE (the ASEAN Joint Sectoral Committee on
Electrical and Electronic Equipment). Upon approval, the testing lab will be listed in the ASEAN website.
4.5. Registration of MEPS and Energy Labelling
With standards in place and the testing body set up, the next action shall be the registration of MEPS and
energy labelling of the product (Figure 4.2).
41
Figure 4.2: Registration Process of MEPS and Energy Labelling of Electrical Appliances
Source: Author.
5.1. Proposed regulations for certificate of registration for manufacturer/importer
A certificate of registration should be issued to the manufacturer or importer of the product. The
certificate will ensure that any person who manufactures or imports any regulated equipment shall apply
to be registered. A renewal period for the certificate is suggested to ensure that the registration of the
products is active and up to date. The products may include electrical equipment and other household
products.
5.2. Proposed regulations for certificate of approval for electrical equipment
Upon the registration of products, the relevant authorities can monitor the approval for electrical
equipment. The certificate of approval (COA) could be issued to such electrical equipment. Hence, with
the certificate, no person shall manufacture, import, display, sell, or advertise any electrical equipment;
any low-voltage equipment which is usually sold directly to the general public; or any low voltage
equipment which does not require special skills in its operation, unless the equipment is approved by the
authority.
5.3. Proposed regulations for energy efficiency label
With the certificates of registration and approval in place, the manufactured electrical equipment which
then meets all the requirements of efficient use of electricity shall be affixed with an energy efficiency
rating label in such form and manner as may be determined by the relevant authority. The general
minimum requirement shall be a recognised test report which could be produced by any of the following
laboratories: (i) lab under IECEE CB Scheme, and (ii) accredited lab by APLAC (Asia Pacific Laboratory
Accreditation Co-operation) MRA.
APLAC developed a regional MRA: (i) accredited lab by ILAC (International Laboratory Accreditation
Cooperation) MRA, and (ii) lab listed as designated testing laboratory under the ASEAN EE MRA.
5.4. Proposed tax rebate
A tax rebate could also be introduced to encourage the registration and certification of equipment.
Some of the tax rebates that could be introduced are those (i)for consumers for every purchase of
energy-efficient equipment, (ii)for manufacturer of green products, and (iii)for house developers for use
and installation of energy-efficient equipment.
Certificate of Registration
(COR) for Manufacturer/
Importer
Certificate of Approval (COA)
for Electrical Equipment
Certificate of Energy-Efficient
LabelTax Incentive
42
Companies providing services to improve energy efficiency are eligible for the following:
1) Pioneer status with an income tax exemption of 100% of the statutory income for 10 years.
2) Investment tax allowance of 100% on the qualifying capital expenditure incurred within 5 years.
The allowance is to be offset against 100% of the statutory income for each year of assessment.
3) Import duty and sales tax exemption on energy-efficient equipment that are not produced locally,
and sales tax exemption on the purchase of equipment from local manufacturers.
6. Role of the General Department of Energy, Ministry of Mines and Energy (MME)
Each stakeholder of MEPS and energy labelling, including the GDEMME, plays an important role in the
success of their implementation. The GDE, as the principal regulatory body of energy efficiency projects,
has the following functions:
1) Coordinate and promulgate the relevant law, regulations, and standards of energy-efficient products
and labelling;
2) Enforce standards into regulations and laws and conversion of the voluntary requirement into
mandatory requirements;
3) Issue certificates of approval of electrical products and energy labelling;
4) Administer, monitor, and audit approved and disapproved electrical products or energy labelling;
5) Review or propose incentives for the use of energy-efficient products or labelling.
7. Road Map
Figure 4.3 summarises the implementation of MEPS and energy labelling.
43
Figure 4.3: Flow Diagram of the MEPS and Energy Labelling Programme
Manufacturers/ Distributors
Product Certification Body
Testing Laboratory
Ministry of Mines and Energy
Source: Author.
A detailed road map is to be provided for the setting up of a framework on labelling of energy-efficient
equipment (Table 4.3).
This includes the following:
1) Moving for inclusion of standards in energy-efficient equipment;
2) Identification of institutions/bodies to be involved in setting up labelling;
3) Identification of electrical equipment for labelling and its ratings;
4) Setting up of testing labs conforming to regional test labs requirements; and
5) Registration of the energy labelling product.
Standard-
writing body
Certification
body
Manufacturer General
Department of
Energy
Report
Application
No
Testing
body
Results
OK?
Certificate
(energy label)
Yes
Verification OK?
Yes
No
44
Table 4.3: Road Map and Implementation Programme for MEPS and Energy Labelling Phase Milestones Activities Target Groups Organisations Involved Time Schedule
Phase 1 Stakeholders engagement GDE Engineering institutions and associations Regulatory bodies Standard-writing organisations Consumer associations
1 year
Phase 2A Setting up of registration requirements
GDE GDE 3 years
Phase 2B Setting up of certification and assessment bodies/standard-working group/testing bodies for MEPS
GDE and ISC GDE and ISC 1 year
Phase 3A Certification and assessment bodies
GDE and ISC GDE and ISC 1 year
Phase 3B Standards working group GDE and ISC All stakeholders 2 years
Phase 3C Testing lab GDE and ISC Appointed lab 5 years
GDE = General Department of Energy, ISC = Institute of Standards of Cambodia, MEPS = minimum energy performance standard. Source: Author.
Phase 1 Stakeholders Engagement
The immediate task foreseen at the initial phase is to gather all stakeholders together to develop MEPS
and energy labelling. This includes identifying relevant stakeholders such as the regulatory bodies, the
SWOs, consumers, engineering institutions, contractors, distributors, manufacturers, design engineers,
and others. The discussion and presentation of draft road map for further inputs and additional ideas
are being sought from the stakeholders. This is followed by the setting of the terms of reference on
MEPS and energy labelling. It is necessary to identify the task force amongst the stakeholders to monitor
the following tasks: (i) registration requirements, (ii) certification/assessment, (iii) standard writing, (iv)
testing and verification, and (v) enforcement.
Phase 2 – Setting Up of Institutions
The next phase shall be the setting up of institutions and identification of their roles as follows:
1) Certification and assessment bodies
The role of certification and assessment bodies is to be established.
45
2) Standard-writing organisations (SWOs)
The role of SWOs (standards for MEPS and procedures in developing and finalising a standard) is to
be established.
3) Testing Bodies
The role of testing bodies (procedures for set-up and compliance to international requirements) is to
be established.
Phase 3 – Setting up of Registration
With the institutions in place, relevant amendments to acts, regulations, and circulars shall be made to
incorporate changes for MEPS and energy labelling. This includes the registration of electrical products
and energy labelling products. Enforcement to monitor the implementation of MEPS and energy
labelling shall also be put up to ensure success of the implementation.
Phase 4 – Implementation
The final phase of the road map shall be the establishment of the following institutions: (i) certification
and assessment bodies, (ii) SWOs, (iii) Cambodian standard on MEPS, (iv) testing bodies with the
establishment of a local test lab for MEPS, and (v) full enforcement of MEPS implementation.
References
Electricity Law of Kingdom of Cambodia, promulgated by Royal Decree No. S/RKM/0201/03 dated 2
February 2001.
Green Growth Inter-ministerial Working Group (2009), The National Green Growth Roadmap. Report by
Kingdom of Cambodia, UNESCAP and Green Growth. Available at:
https://www.oneplanetnetwork.org/sites/default/files/cambodia_the_national_gg_roadmap_c
ambodia_2009.pdf (accessed 20 April 2020).
Ministry of Environment (2019), Environment and Natural Resources Code (in ninth draft): Sustainable
City Plan for Phnom Penh, Phnom Penh.
Ministry of Environment (2019), Environment and Natural Resources Code (in ninth draft): Sustainable
City Strategic Plan for Secondary Cities. Phnom Penh.
Ministry of Industry, Mines and Energy (MIME) (2013), Energy National Policy, Strategy and Action Plan
on Energy Efficiency in Cambodia. Phnom Penh: MIME.
Ministry of Planning, Royal Government of Cambodia (2019), National Strategic Development Plan
2019–2023, Phnom Penh: Ministry of Planning, Royal Government of the Kingdom of Cambodia
National Council for Sustainable Development (NCSD) (2016), Sustainable City Plan for Phnom Penh
Green City Strategic Planning Methodology. Phnom Penh: NCSD.
Royal Government of Cambodia (2018), Rectangular Strategy Phase IV (2018–2023). Phnom Penh.
Royal Government of Cambodia (2013), National Policy and Strategic Plan on Green Growth 2013–2030.
Phnom Penh.
46
Chapter 5
Education and Campaigns
Leong Siew Meng
1. Introduction
Energy efficiency and conservation (EEC) is an important agenda in every country’s economic
development because it contributes to two critical issues common to most economies: energy security
and environmental sustainability. As a first step of EEC promotion, a responsible government body should
implement its education and campaign programmes. The education and campaign surely contribute to
encourage Cambodians to be aware of and acquire interest in EEC. Saving energy, especially electricity
through EEC promotion including education and campaigns, can delay the construction of power plants.
It can also cost less than generating, transmitting, and distributing electricity from power plants, hence,
providing multiple economic and environmental benefits. For EEC programmes to have impact, every
aspect of information on EEC activities needs to be disseminated to the whole population nationwide,
which includes the business, professional, and academic communities as well as the public.
This chapter discusses various communication and promotion methods for education and campaigns
through public and professional forums, printed media with practical EEC information, websites, home
energy reporting, school system, etc. EEC activities involve a wide spectrum of methods and technologies,
which can be broadly classified as no or low-cost, medium-cost, and high-cost or investment-scale
measures. In general, the planning and implementation of education and promotion campaign activities
will require both technical input and government administrative effort with commitments.
2. Role of the General Department of Energy
The success of education and campaigns depends on the effective planning and execution of the plans.
The functions of the General Department of Energy (GDE) are summarised as follows:
1) Plan education and campaign activities, including estimation of budget and resource requirements.
2) Generate awareness and interest of EEC in the residential, commercial, and industry sectors.
3) Assign a responsible person or a committee to plan and implement EEC education and promotion
campaign activities.
4) Generate awareness and interest of EEC in the educational system.
Figure 5.1 shows the structure for GDE’s roles in organising and interacting with stakeholders in other
government departments, professional and academic bodies, and non-governmental organisations. A
consultative approach with these organisations and bodies is recommended, such that (i) the professional
and academic bodies will provide input in developing professional training and continuous professional
development (CPD) programmes; (ii) non-governmental organisations and trade associations will provide
input in developing roadshows and media campaigns; and (iii) other government ministries or
47
departments will provide input in developing EEC programmes of activities for government buildings and
school syllabuses.
Figure 5.1: Structure of GDE’s Role in Implementing EEC Education and Campaign
CPD = continuous professional development, GDE = General Department of Energy, NGO = non-governmental organisation. Source: Author.
3. Content of EEC Education and Promotion Campaigns
There is no single measure to achieve EEC. Therefore, the planning and implementation of EEC education
and campaign activities would require a multifaceted approach. This approach can be simplified by
categorising various EEC education and campaign activities under clusters of activities (Figure 5.2).
The following describes the various clusters of EEC education and campaign activities:
1) General awareness: The cluster of general awareness campaigns should be targeted mainly at the
public and the household sector. This cluster aims to generate basic awareness amongst the public
on the needs and simple ways of energy conservation and savings.
2) Fundamentals: The cluster on EEC fundamentals should be introductory targeting at the
commercial and industry sectors, especially on ‘low-hanging fruits’ in the EEC. The objective of
this cluster is to introduce the concepts and fundamentals of EEC measures to the business
communities in the commercial, residential, and industry sectors. For the residential sector, the
target would be the housing developers and builders.
3) Roadshows and forums: This cluster aims to disseminate information on the practices and benefits
of EEC measures in various business operations, such as hotels, shopping malls, restaurants,
hospitals, and office buildings in the commercial sector, and textile factories, food and beverage
GDE
- Dept of Energy Technique & Energy
Business Policy
Professional and academic
bodies
Professional training:
train-the-trainers
CPD Programmes
Public through NGOs and trade
associations on roadshows and media
Public Awareness: campaigns, pamphlets, and awards
Government ministries/
departments
Government buildings
Education System
48
factories, breweries, furniture factories, cement plants, etc. in the industry sector. Regular
roadshows and forums will provide updates on EEC practices and government EEC plans.
4) EEC information: For the cluster of EEC information, pamphlets, guidelines, and standards, such
as minimum performance standards (MEPS), will be developed. This cluster highlights that
appropriate selection and use of appliances and equipment will save energy.
5) Media campaigns: This cluster aims to generate awareness and disseminate information through
printed media, television, and websites to reach out to the whole population.
6) Education for professionals: Education is an important part of the EEC campaign because the
professionals and practitioners in the commercial and industry sectors are the ones who operate
the machineries and equipment that consume energy.
7) Education in the school system: Educating schoolchildren and university students would provide
the best opportunity to inculcate behavioural changes towards the adoption of the EEC in daily
lives. This cluster would involve the development of syllabus in the education system.
8) Publicity and national awards: As part of the publicity programmes, national energy awards would
provide official recognition of EEC efforts to the commercial and industry sectors. The school
system may introduce EEC project competitions and awards to encourage the uptake of EEC
practices and culture amongst the younger generations.
Figure 5.2: Cluster of EEC Education and Campaign Activities
CPD = continuous professional development, EEC = energy efficiency and conservation. Source: Author.
Fundamentals General
awareness
Roadshows and forums
Publicity and national awards
EEC info for residential,
commercial, industrial sectors
Media campaigns
Education – School syllabus
Education - Professional
- CPD
49
4. School Syllabus
The adoption of EEC concepts and practices by people would involve behavioural changes. The best way
to achieve this objective is to start with educating schoolchildren and university students in adopting EEC
lifestyles. The development of the EEC school syllabus should consider the elementary, intermediate, and
advanced levels. It is recognised that the development of the school syllabus is within the authority of
Cambodia’s Ministry of Education, Youth and Sport. Therefore, the GDE needs to consult with the ministry
and other stakeholders to work out the best arrangement for the development of an EEC syllabus. This
section provides guidance and input for the development of an EEC syllabus.
4.1. Elementary level
The elementary level school syllabus aims to educate primary school students on a basic understanding
of energy and environment, and the benefits of the EEC. The following topics are recommended to be
included in the primary school syllabus:
1) Energy and environment
a) Types of energy: non-renewable energy (diesel, petrol, natural gas, liquefied petroleum
gas (LPG), coal, electricity); renewable energy (solar energy, biomass, biogas, etc.)
b) Forms of energy: heat, light, sound, electrical energy, etc.
c) Use of energy
d) Effects of energy usage on environment
2) Energy conservation and energy efficiency
a) What is energy conservation and energy efficiency?
b) Can energy be saved? What is the difference between energy conservation and energy
efficiency?
c) Simple and practical ways to conserve energy
d) Simple and practical ways to reduce energy consumption
3) Benefits of the EEC
a) Conserves energy
b) Reduces energy
c) Reduces energy bills
4.2. Intermediate level
The objective of the intermediate level school syllabus is to target secondary school students with EEC
topics that can provide these students greater knowledge and skills. The scientific principles of the EEC to
be taught at this level should correspond with the level of science subjects being taught in secondary
schools. The following topics are recommended to be included in the secondary school syllabus:
50
1) Conversion of energy sources
a) Electricity
b) Solar photovoltaic (PV)
c) Thermal energy (heat, steam, etc.)
2) Application of energy
a) Building services (air-conditioning and mechanical ventilation, lighting, refrigerators, lifts and
escalators, etc.)
b) Transportation
c) Medical equipment
d) Manufacturing processes
e) Building construction
3) Principles of EEC
a) Energy units and measurements
b) Specific energy consumption
c) Energy efficiency indicators (EEIs)
d) Basic heat transfer
e) Basic EEC measures
4) Basic EEC problem–based learning project assignment
a) Examples: walk-through audit of school facilities; small solar PV project, etc.
4.3. Advanced level
The objective of the advanced level school syllabus is to target college and university students to impart
higher level of skills and knowledge in EEC. The syllabus should be developed to enable students to
appreciate and correlate the application of principles learned in their science and technical subjects. The
following topics are recommended to be included in the secondary school syllabus:
1) Understanding of energy units, conversion, and measurements
2) Understanding and application of EEC practices
a) Buildings: the concepts of passive and active energy efficiency design measures
b) Manufacturing process: understanding of significant energy users and potential energy
measures
3) Understanding of energy performance data and trending
51
a) National energy statistics
b) EEI for the commercial sector
c) EEI for the industry sector
4) EEC problem-based learning project assignment
a) Examples: Identify and quantify the energy saving potential of a facility through walk-
through audit, conduct of interviews, and collection of energy consumption data and
other required data. The project assignment will evaluate the economic viability of
implementing EEC measures that the student project team identifies.
5. Media campaigns
Media campaigns are significant because they can potentially reach out to the masses in the country
within relatively short time. Media campaigns can be designed and strategised to reach out to different
target groups, for example, household owners, consumers, and business communities. For more effective
media campaigns, the GDE should consider using an EEC mascot design that would appeal to the public
and capture people’s attention and interest.
The objectives of media campaigns under these two broad sections of the population are as follows:
1) Household owners and consumers
a) Generate awareness on the benefits of the EEC, which can be translated as ‘putting
money back to their pockets’ based on the concept of ‘using less energy to obtain the
same service’;
b) Generate positive attitude towards energy efficiency and energy savings, i.e. towards
changing behaviour;
c) Disseminate information on labelling of appliances and equipment that can help
identify energy-efficient products.
2) Business communities
a) Generate awareness on the benefits of EEC practices that would result in energy-
efficient operations;
b) Generate positive attitude with confidence towards energy efficiency and energy
savings through highlights of success stories or case studies;
c) Highlight and educate stakeholders on the availability of energy-efficient techniques
through various measures:
▪ No/low-cost measures
▪ Medium-cost measures
▪ Investment-scale measures
52
d) Educate stakeholders on the significance of EEC practices towards national energy
security, energy equity, and environmental sustainability.
With today’s advanced communications, more options are available to disseminate information. Media
campaigns can be grouped under three types of action plans as detailed below and as illustrated in Figure
5.3.
1) Printed media – newspapers, pamphlets, publications, banners, buntings, and posters.
2) TV broadcasts and advertisements – broadcast of EEC events and documentaries, and TV
advertisements
3) Dedicated EEC website – announcement of EEC activities; energy saving measures for the
commercial, residential, and industry sectors; success stories or case studies; new
developments in EEC locally and overseas
Figure 5.3: Methods of Media Campaigns
Source: Author.
6. Pamphlets to Promote Energy Efficiency and Conservation
Pamphlets for promotional activities have been the traditional method of disseminating information to
the public. Despite the advancement in communication, this traditional method of printing and
distributing pamphlets is still being practised in many ASEAN countries. EEC pamphlets should be prepared
to meet the requirements of the respective sectors. In view of the extensive and technical nature of EEC
TV broadcasts and
advertisements
Printed media
Website
53
information, it is more practical to prepare guidebooks instead of pamphlets for the commercial and
industry sectors. Therefore, this section will only address the pamphlet contents for the residential sector.
6.1. Contents of EEC pamphlets for households
EEC pamphlets should comprise basic energy-saving tips such as the following:
1) Introduction of EEC at home
a) Explain what energy efficiency is.
Energy efficiency means using energy (which is mainly electricity) wisely, without wasting
it, so that its consumption is reduced. Such reduction will mean lesser electricity bills. In
other words, practicing EEC can save money.
b) Why is it necessary to use energy efficiently?
The objectives are
• to save fossil fuel (oil, gas, and coal) as increasing energy consumption depletes
resources, increases prices (dependent on importation), and produces greenhouse
gases (GHGs) that contribute to climate change;
• to preserve the environment; and
• to save on energy (electricity) bills
2) Understanding household electricity consumption, by providing examples
a) on how to read the monthly electricity bill, i.e. besides finding out the amount to pay,
what is the electricity consumption unit?
b) to illustrate that the air conditioner is the largest energy-consuming appliance in the
monthly electricity consumption of a typical household; and to show the energy
consumption of an air conditioner, which is based on the power rating of the air
conditioner and usage hours.
Example:
A typical 1.5 hp air conditioner has a nominal power rating of 1.2 kW and an approximate
load factor of 0.6. The estimated electricity consumption for the use of 1.5 hp air
conditioner for 5 hours per day for 30 days is given below.
𝐴𝑖𝑟 𝑐𝑜𝑛𝑑𝑖𝑡𝑖𝑜𝑛𝑖𝑛𝑔 𝑘𝑊ℎ = 1.2 𝑥 5 𝑥 0.6 𝑥 30 = 108 𝑘𝑊ℎ
If the household used two units of 1.5 hp air conditioners in a month, the estimated total
electricity consumption for this household would be:
𝑇𝑜𝑡𝑎𝑙 𝑎𝑖𝑟 𝑐𝑜𝑛𝑑𝑖𝑡𝑖𝑜𝑛𝑖𝑛𝑔 𝑘𝑊ℎ = 108 𝑥 2 = 216 𝑘𝑊ℎ
If this household’s electricity consumption is 500 kWh per month, the percentage share
of air-conditioning consumption of electricity would be about 52%.
54
The key messages of this example are:
▪ The largest share of electricity consumption in a typical household in hot and humid
climate is the use of air conditioners.
▪ The electricity consumption of appliances in a household can be reduced by (i)
reducing the usage hours, e.g. switch off electrical appliances when it is not required;
and (ii) having energy-efficient appliances with lower power rating but can meet the
capacity requirements.
3) Tips on reducing electricity bills at home
There are opportunities to improve the efficiency of electricity use at home. Wise and efficient
use, including the selection of energy-efficient appliances, can conserve energy, save money,
and help protect our environment. The primary method is to analyse our electricity usage and
assess where it can be comfortably controlled or used more efficiently. One can conduct
his/her own energy audit at home. Figure 5.4 illustrates the electricity consumption pattern
of a typical home vs an energy-efficient home.
Figure 5.4: Electricity Consumption of a Typical Home vs an Energy-efficient Home
Note: Figure 5.4 is for illustration purposes and is not based on actual data.
Source: Author.
Energy-saving tips on reducing electricity consumption of appliances will be useful for household
residents. Including these tips on efficient use of appliances in pamphlets is recommended as part of the
dissemination campaign on EEC to the public in the residential sector. Tables 5.1 to 5.6 provide practical
energy-saving tips for efficient use of common appliances in households.
0
200
400
600
KW
h/m
on
th
Typical Home Energy-efficient Home
55
Table 5.1: Tips for Efficient Use of Air Conditioners
Guide What to Do
1. Installation • Select energy-efficient air conditioners.
• Make sure air conditioners are installed away from direct sun rays.
• Avoid oversizing; ensure that the air conditioner is the correct size for the room to be air-conditioned.
2. Operation • Do not block air distribution from air vents.
• Check and adjust the thermostat to give a comfortable temperature; the recommended temperature setting is between
24C and 26C (in steady state operation).
• Close windows and doors to stop air leakages to prevent outflow of cool air and reduce cooling load.
• Insulate roof or ceiling and shield windows from the sun to reduce cooling load.
3. Maintenance • Clean air filter periodically to optimise operation.
• Clean the outside coil fins twice a year.
• Provide regular maintenance to facilitate efficient operation and prolong the equipment lifespan.
• Check and adjust the thermostat for a comfortable temperature.
• Check the level of system refrigerant once a year.
• Clean the blower unit coils once a year.
Source: Author.
Table 5.2: Tips for Efficient Use of Lighting
Guide What to Do
1. Installation • Avoid excessively high illuminance level, i.e. too bright for the applications, e.g. 300–400 lux for reading and writing, 150–300 lux for kitchens, 150 lux for bathroom, and 100 lux for bedroom are recommended.
• Check that the lights used are energy efficient that has high luminous efficacy, i.e. the ability to emit visible light using less amount of power, e.g. compact fluorescent lamps, LED lamps, etc.
• Separate light-switching circuits in large areas, such as the living room, so that unnecessary lights can be switched off when they are not required.
• Use timer or photosensor to switch off outdoor night security lights during daytime.
2. Operation • Switch off lights when not required.
Source: Author.
56
Table 5.3: Tips for Efficient Use of Electric and Microwave Ovens
Guide What to Do
1. Oven door gasket • Regularly inspect the door gasket for signs of wear and tear.
• Check for defects in the hinges of the oven door.
• If any fault on the gasket or hinges is detected, call an authorised person to repair/replace the part.
Source: Author.
Table 5.4: Tips for Efficient Use of Home Entertainment Devices
Things to Check What to Do
1. Television, personal
computer, music player and
radio
• Ensure that the television, personal computer, and stereo are unplugged when not in operation (standby mode consumes electricity).
• Make sure that the energy saver function of the computer is activated when left idle in between activities.
Source: Author.
Table 5.5: Tips for Efficient Use of Refrigerators
Guide What to Do
1. Selection and installation ▪ Select an energy-efficient refrigerator that has an inverter compressor.
▪ Avoid using an oversized refrigerator; choose the right capacity of refrigerator to suit your needs.
▪ Avoid enclosing the sides of the refrigerator with kitchen cabinets. Leave sufficient gaps to facilitate heat dissipation from the condenser coils, which are normally located at the back of the refrigerator.
▪ Do not place the refrigerator in a warm area, e.g. area exposed to direct sunlight or near a stove or oven.
2. Operation ▪ Avoid overloading the refrigerator; unblock or allow space around food in the refrigerator for air to freely circulate.
▪ Leave hot food to cool down naturally before storing in the refrigerator.
• Keep the compartments closed to avoid unnecessary loss of cold air when door is opened.
▪ Avoid opening refrigerator frequently; do not leave the door open for a long time.
57
▪ Check the temperature of the refrigerator compartment; 5C is recommended to be set as the coldest.
▪ Check the temperature of the freezer; -18C is recommended for the freezer.
3. Maintenance ▪ Keep the condenser coils clean. Dust and dirt on the condenser coils will reduce refrigerator efficiency.
▪ Check and ensure the door gasket is in good condition by
- closing the door on a sheet of paper - replace door gasket or adjust the alignment of the
refrigerator/freezer if the sheet of paper is easily removed
▪ If the refrigerator is not a frost-free model,
- check for frost in the freezer compartment; - do not let frost thickness to exceed 6 mm; - switch off to defrost and remove excess water before
restarting.
Source: Author.
Table 5.6: Tips for Efficient Use of Electric Instant Water Heater
Guide What to Do
1. Installation • Select an energy-efficient water heater with a suitable capacity.
• For low-volume requirement such as shower-only water
heating, select tankless or demand-type water heater, which
can avoid standby energy losses when compared with a storage
water heater.
2. Operation • Fix leaky faucet, showerhead, or pipe.
• Avoid setting a high temperature for the shower heater,
especially during hot weather.
• Reduce temperature setting after the shower is turned on and
when lower water temperature can be tolerated.
• Avoid prolonged shower time.
• Switch off electric water heater when not in use.
Source: Author.
58
7. Home Energy Report
A home energy report is a useful tool to inform household owners if their electricity consumption for the
month exceeds the corresponding average consumption per household in their area or district of
residence. This reporting aims to provide a friendly feedback to the household owners concerned so that
they get a chance to review and try to reduce their electricity consumption based on the
recommendations, which will be provided in the home energy reports. It is intended to help household
owners better assess their electricity consumption and effectively pay less for their effort in reducing their
energy use.
Household electricity consumption data by district or area would be available with the power utility
company, the Electricite du Cambodge (EDC). Such data can be put to good use by comparing electricity
consumption of their home customers by area or district. As illustrated in Figure 5.5, households whose
electricity consumption exceeds the average consumption of similar homes in the same area or district
for, say, 3 consecutive months will receive a friendly notification in the form of letters or emails giving the
following information:
1) A statement that the household concerned has consumed electricity much higher than similar
homes in the neighbourhood;
2) A graph illustrating the comparison similar to Figure 5.5;
3) Energy efficiency tips on how to manage and reduce energy consumption in typical households;
GDE’s web portal with EEC tips and tools, if available, should be referred to in the notification.
Figure 5.5: Home Energy Report Comparing Electricity Consumption in the Same Area
Note: Figure 5.5 is for illustration purposes and is not based on actual data.
Source: Tenaga Nasional Berhad, Malaysia, https://myelectricitybill.my/green_tips.html
- 200 400 600 800 1.000 1.200 1.400
Energy-efficient Similar Home
Similar Home - Average
Your Home
kWh/month
59
Figure 5.6 illustrates a method of deriving the average value of monthly electricity consumption based on
the electricity consumption data in the neighbourhood of a chosen area or district. Compiling the cluster
of average home data to work out the average monthly electricity consumption is a simple method in
view of the large amount of data that can be anticipated in data collection and analysis.
Figure 5.6: Example of Deriving the Average Monthly Electricity Consumption in a Neighbourhood
Note: Figure 5.6 is for illustration purposes and is not based on actual data.
Source: Author.
As a follow-up, a feedback report should be sent to homeowners to inform them of their individual
household electricity consumption compared with the same period in the previous year. Figure 5.7
illustrates such comparison of electricity consumption for self-monitoring purposes. Such follow-up
reporting will be useful and effective to generate continuous awareness and interest amongst
homeowners in the residential sector, so that the EEC will continue to be practised in people’s daily lives.
The points made in the above have shown that home energy reporting is an easy and practical way of
generating awareness and interest in people to adopt EEC practices. The implementation of this
programme should be worked out and developed by the GDE and the EDC.
0
100
200
300
400
500
600
700
800
HomeCluster A
HomeCluster B
HomeCluster C
HomeCluster D
HomeCluster E
HomeCluster F
HomeCluster G
HomeCluster H
HomeCluster I
kWh
/mo
nth
/ho
use
ho
ld
Average 480 kWh/month in a neighbourhood
60
Figure 5.7: Comparison of Personal Electricity Consumption of the Same Periodin the Preceding Year
Note: Figure 5.7 is for illustration purposes and is not based on actual data. Source: Tenaga Nasional Berhad, Malaysia.
8. Road Map (2020–2025)
The key factor for the EEC plan to succeed is to reach out to the masses in the three sectors – commercial,
residential, and industry. If the public and business entities are fully aware and interested in EEC practices,
people will change their behaviour, which can be translated into energy savings nationwide. Education –
through the introduction of EEC topics in the syllabi of primary and secondary schools and universities –
should have a greater impact on behavioural change amongst the younger generation. The impact will be
great. Overall, this chapter has addressed the task of education and campaigns to reach out to the masses.
Table 5.7 outlines the road-map activities, which can be conducted in parallel. Some of the activities may
be carried forward to the following year.
Table 5.7: Education and Campaign Road-map Activities (2020–2025)
Phase Description of Activities
Remarks
Phase 1a: 2020–2021 The GDE to head the formation of a task force to plan education and campaigns
To generate interest in EEC campaigns, it is suggested to design and develop an EEC mascot that champions the EE agenda.
Phase 1b: 2020–2021 Conduct EE awareness campaigns, roadshows, mini exhibitions, and technical forums to disseminate information on EEC measures and savings.
Awareness campaigns to generate interests in EEC measures and energy savings
Phase 1c: 2020–2021 Publication of EEC pamphlets To publish energy-saving tips and measures
6.000
6.200
6.400
6.600
6.800
7.000
7.200
7.400
Jan-Jul 2018 Jan-Jul 2019
kWh
How are you doing compared with the previous year?
61
Phase 2a: 2021–2025 Based on data collection and analysis, home energy reports to be distributed to affected households
The GDP and the EDC to work out the preparation of home energy reports for distribution
Phase 2b: 2021–2025 Media campaigns Continuous campaigns through website, printed media, and television
Phase 2c: 2021–2025 EEC school syllabus Continuous development
Phase 2d: 2021–2025 Professional training courses Continuous development
Phase 3a: 2022–2025 Technical forums to disseminate information on EEC achievements
To share success stories and experiences
Phase 3b: 2023–2025 Conduct national EEC competitions and awards to recognise EEC efforts and achievements
Commercial and industry sectors
EE = energy efficiency, EDC = Electricite Du Cambodge, EEC = energy efficiency and conservation, GDE = General Department of Energy. Source: Author.
62
Chapter 6
Data Collection to Establishment of Energy Efficiency Indicators
Leong Siew Meng
1. Introduction
After the General Department of Energy (GDE), Ministry of Mines and Energy (MME) has implemented
the many action plans, the GDE has to assess how each energy efficiency and conservation (EEC) action
plan contributes to saving energy consumption in Cambodia. For this assessment, generally the GDE also
must produce a benchmark showing the current energy efficiency level of each industry sub-sector, each
commercial building sub-sector, and each household per area or district. Thus, the collection of data and
production of energy efficiency indicators (EEIs) are particularly important.
Establishing EEIs refers to the report of the International Energy Agency (IEA, 2014a), entitled Energy
Efficiency Indicators: Fundamentals on Statistics 2014. This report is complemented by a companion
document, Energy Efficiency Indicators: Essentials for Policy Making, (IEA, 2014b). The former focuses on
what data to use and how to collect them. The latter is aimed at providing tools and methodology to
determine the priority areas for the development of indicators and how to select and develop the data
and indicators that will best support energy efficiency policy.
Referring to IEA’s manuals, this chapter presents the requirements for data collection and establishment
of EEIs for the commercial, residential, and industry sectors. Collection of quality energy consumption
data is important for planning the country’s policies and priorities to support economic development. It
is equally important to develop indicators to compare energy efficiency trends at the macro and micro
levels, i.e. energy performance at the national level and energy performance at each sector and sub-sector
levels.
The EEIs are basically indicators. They may be disaggregated indicators to indicate and compare the extent
of energy efficiency with benchmark values or with one another within the same category or sub-sector.
In general, the EEIs will help demonstrate if one thing is more energy efficient than another. They may be
aggregated, for example, to show total appliance energy consumption per type of appliance, or
disaggregated, for example, to show the average cooling consumption per floor area of a building. In
general, the EEIs are usually composed of an energy consumption as numerator and an activity data as
denominator. The exact definition of the EEIs varies from sector to sector, and sub-sector to sub-sector.
Therefore, the exact definitions of EEIs are given in the respective section for each of the commercial,
residential, and industry sectors.
Collection of relevant and consistent data is the key factor in building meaningful EEIs. In other words,
without relevant data, there are no indicators; and without indicators, the shortfall of information
continues and will lead to difficulties in planning and optimising measures and policies, as well as tracking
progress and monitoring the effectiveness of energy efficiency policies and measures. According to the
IEA, three types of information are needed to understand the context and policy options for greater
63
effectiveness in energy planning, review, and policy updates based on measured performance through
diligent data collection and analyses of the EEIs:
1) Why the end users use energy the way they do, i.e. the driving forces of energy demand;
2) What currently exists and how it performs, i.e. the state of energy consumption; and
3) Policy options and potential impact, i.e. the response that policies should enable.
2. Regulatory Requirements and Designated Premises
Establishment of the EEIs requires relevant data collection which includes production data for the industry
sector and building operational data. However, such data are normally in the safekeeping of the private
sector. In fact, many business entities consider energy consumption and activity data proprietary
information not to be divulged to others, especially business competitors. Without a legislative framework
and regulatory requirements, it is not possible to get the private sector to submit the required data
voluntarily. If the programme of establishing the EEIs were voluntary, the challenges faced could be poor
quality data, and inconsistency and insufficient collection of data. To address this gap, a legal framework
should be established to set up regulatory or mandatory requirements of submitting energy consumption
and activity data. In other words, a top–down approach is recommended to be adopted to collect quality
data and establish the EEIs.
In setting up the legal framework, the mandatory requirements of submitting energy consumption and
activity data should be confined to designated premises so that small business entities are exempted from
submission. Designated premises are business entities in the commercial and industry sectors that
consume energy above a threshold value of yearly energy consumption set by regulations. They will be
required to engage a certified energy manager (CEM) (who may be in-house or outsourced) and submit
energy management reports containing the required data. Table 6.1 shows the threshold value of yearly
energy consumption in various countries that mandates a designated premise to submit its energy
management report, which includes energy consumption and activity data.
Table 6.1: Comparison of Threshold Values in Some ASEAN Countries and Japan
Country Threshold Value Remarks
Thailand 20 mil MJ/y (energy) Required to comply with the Energy Conservation Promotion Act 1992
Singapore 54 mil MJ/y (energy) Threshold value applies, subject to yearly consumption in at least 2 out of 3 preceding calendar years, as required under the Energy Conservation Act.
Malaysia 6,000,000 kWh/y (electricity) Required to appoint a certified energy manager and submit energy
64
Under proposal in Energy Efficiency and Conservation Act (EECA): 20 mil MJ/y
(energy)
management reports under the Efficient Management of Electrical Energy Regulations 2008. The draft Energy Efficiency and Conservation Act is pending to be tabled in Parliament for approval.
Indonesia 6,000 toe/y (energy) (or 251 mil MJ/y)
Government Regulation No. 70/2009 on Energy Conservation
Japan Type 1: 3,000 kL/y (crude oil equiv.) or 115 mil MJ/y Type 2: 1,500 kL/y (crude oil equiv.) or 57 mil MJ/y
EC Act Crude oil conversion: 9,126 kCal/La
Cambodia Suggestion: 3,000,000 kWh/y (10 mil MJ/y)
To be established
Note: a EECJ (2006). Source: Compilation by author based on the acts and regulations of each country.
The significance of the threshold value is that if the value is set too low, more business entities in the
commercial and industry sectors will be required to engage an energy manager and submit energy
management reports. On the other hand, if the threshold value is set too high, very few premises will be
subjected to the EEC mandatory requirements. As shown in Table 6.1, Cambodia can consider setting the
threshold value at 3,000,000 kWh per year (or 10 mil MJ/y), which is half the threshold value set in
Malaysia and Thailand. Without sufficient data, it is difficult to quantify and justify setting the threshold
value at 3,000,000 kWh per year.
However, as a guide and approximate estimation based on Cambodia’s energy statistics for 2018,3 the
number of premises that may be subjected to the mandatory requirements, if the threshold value is set
at 3,000,000 kWh/y, is estimated in Figure 6.1.
3 Information was obtained from the Cambodia’s energy statistics for 2018 reported by Heang Theangseng at the
first meeting of ERIA Research Project FY2019, Working Group on the Preparation of Energy Outlook and Analysis
of Energy Saving Potential in East Asia Region, 17–18 December 2019, Jakarta.
65
Figure 6.1: Energy Consumption of Cambodia in 2018
Source: Theangseng (2019).4
Energy consumption of the industry sector in 2018: 1,727,030 MWh
Number of manufacturing factories in 20185: 1,528
Average energy consumption per factory: 1,727,030
1,528𝑥 1,000 = 1,130,255 𝑘𝑊ℎ
Half of these factories are assumed to be affected if the threshold value is set at 1,130,255 kWh.
Therefore, the number of factories affected would be about 764. If this threshold value were raised to a
higher value at 3,000,000 kWh/y, the number of premises is expected to be lower as the relationship is
inversely proportional. Based on this relationship, the number of premises for threshold value set at
3,000,000 kWh/y is estimated as follows:
New number of premises = 764 𝑥1,130,255
3,000,000 = 288
For estimation purposes, this number of premises is rounded up to 300.
Energy consumption of the commercial sector in 2018: 2,078,490 MWh
Based on the 2018 energy statistics,6 the energy consumption of the commercial sector is fairly similar to
that of the industry sector. Accordingly, the designated premises in the commercial sector are assumed
to be about the same as those of the industry sector, i.e. 300 premises, making an estimated total of 600
premises for both the commercial and industry sectors.
4 Heang Theangseng reported on Cambodia’s energy statistics for 2018 at the first meeting of ERIA Research Project FY2019, Working Group on the Preparation of Energy Outlook and Analysis of Energy Saving Potential in East Asia Region, 17–18 December 2019, Jakarta. 5 Source of information: Open Development Cambodia (https://opendevelopmentcambodia.net/topics/industries/) 6 See footnote no. 4.
66
However, the above is only a rough estimate and is suggested to be used as a guide in view of limited
availability of data. Therefore, the estimated number of premises needs to be verified against the existing
records of business entities, which consumed energy equal to or greater than the suggested threshold
value of 3,000,000 kWh/y (or 10 mil MJ/y).
3. Role of the General Department of Energy
Data collection and establishment of the EEIs are major tasks that require budgets, time, and workforce
resources. However, it is of utmost importance that a legal framework with regulatory requirements is
established before any work on the collection of data and establishment of the EEIs can commence.
Assuming that the regulatory requirements are set up, the roles of GDE are summarised as follows:
1) Establish a dedicated team to plan on data collection.
2) Collect, collate, analyse, and update data on a continuous and professional basis, adhering to
the principles of non-disclosure practices.
3) Establish the EEIs by sector and sub-sector;
4) Liaise with and assist/guide the commercial and industry sectors.
It is recommended that the GDE engage stakeholders such as the trade associations, the professional
bodies, and the academia in the planning phase. The objective is to make a practical plan such that once
the plan and administrative process are rolled out, the plan will be widely accepted and implemented
smoothly without much hiccups. The planning of labour resources required by the GDE should be based
on the anticipated number of designated premises. GDE staff responsible for the safekeeping and analyses
of data should not divulge information to safeguard the interests of business entities.
4. Validation and Analysis of Energy Consumption Data
Validation and analysis of energy consumption data are important steps before the EEIs are established.
The accuracy and relevance of the EEIs depend heavily on the quality of data. Before looking into the
details and methods of validation and analysis, it is necessary to understand the concept of EEI
establishment. Figure 6.2 illustrates IEA’s concept of the EEI pyramid. It explains the various levels of
indicators and shows how indicators are organised into a hierarchy. Having understood the concept and
data requirements, GDE’s dedicated team will need to design and prepare a precise format for data
collection. The objective of this data format is to ensure that the designated premises submit quality data
according to the requirements. The GDE needs to reach out to business entities through technical forums
to explain the data formats so that erroneous data can be minimised; hence, more accurate and
meaningful EEIs can be derived.
67
Figure 6.2: Overview of Energy Indicators Pyramid
TFC = total final consumption. Source: IEA (2014a).
Starting from the top of the pyramid in Figure 6.2, total final consumption (TFC) per gross domestic
product (GDP) is an aggregated indicator. IEA’s concept of EEIs is a ‘pyramidal approach’ starting from the
most aggregated level at TFC/GDP to the most disaggregated level at unit energy consumption. The
TFC/GDP indicator has been compiled in Cambodia’s energy statistics. This report focuses on the
establishment of EEIs for three sectors in Cambodia – commercial, residential, and industry. Therefore,
this report primarily covers the development of the EEIs in terms of energy intensity for sub-sectors, such
as hotels, retail malls, office buildings, and hospitals in the commercial sector; and textiles, food and
beverages, breweries, cement, etc.in the industry sector. The objective of sub-sector energy intensity–
type of EEIs is to compare energy efficiency within end-use sectors or sub-sectors. When sufficient EEI
data are established, analyses can be made to develop benchmarking values for each respective sub-
sector. Examples on this will be shown in the respective sections.
In general, the establishment of the EEIs require more disaggregated information. The EEIs are basically
intensities, presented as a ratio between energy consumption (measured in energy units) and activity data
(measured in physical units) shown as follows:
𝐸𝑛𝑒𝑟𝑔𝑦 𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑖𝑛𝑑𝑖𝑐𝑎𝑡𝑜𝑟 =𝐸𝑛𝑒𝑟𝑔𝑦 𝑐𝑜𝑛𝑠𝑢𝑚𝑝𝑡𝑖𝑜𝑛
𝐴𝑐𝑡𝑖𝑣𝑖𝑡𝑦 𝑑𝑎𝑡𝑎
TFC/
GDP
Sector energy intensity
Sub-sector energy intensity
Unit energy consumption
National energy statistics
Aggregated indicators
Disaggregated indicators
68
The EEIs are computed at the end-use or sub-sector level, or at a more disaggregated level, which is the
unit energy consumption level. For example, within the residential sector, space cooling energy
consumption per floor area is an EEI at the end-use level, and energy consumption per unit of appliance
is an EEI at the unit consumption level.
It is prudent to plan and design a good template or format to collect quality data so that validation and
analysis of energy consumption data will be made easier. For better control and monitoring of data
submission, the submission of energy management reports containing energy consumption data should
be made every 6 months. Each report should contain the monthly energy consumption data.
Based on the details given in Section 6.5.1, by working out the building energy intensities (BEIs), validation
of data can be made (Figures 6.3 and 6.4). The data lying outside the cluster of relevant data are outliers.
These would not be included in the computation of BEI average values for the purpose of establishing BEI
benchmark values for the respective sub-sectors after collecting data for at least 3 years. In addition, for
the commercial sector, BEI values computed can be compared with the indicative BEI values for the
respective sub-sectors (Table 6.2) to gauge the relevance of the computed BEI values. For example, if the
computed BEI value is too low or too high compared with the values given in Table 6.2, the affected data
should be checked and verified with the premises concerned.
Figure 6.3: Example on Validation of Data based on Analysis of BEI Values for Hospitals
BEI = building energy intensity, GFA = gross floor area.
Source: Author’s previous work with ERIA.
0
100
200
300
400
500
600
- 1.000 2.000 3.000 4.000 5.000 6.000
BEI vs GFA for medium-sized hospitals
Outlier data
69
Figure 6.4: Example on Validation of Data based on Analysis of BEI Values for Retail Malls
BEI = building energy intensity, GFA = gross floor area.
Source: Author’s previous work with ERIA.
5. Establishment of EEIs
The establishment of EEIs for the three sectors is different as the definition of EEI varies. Therefore, the
details on the establishment of EEIs are provided separately in the respective sectors. However, the
general process that the GDE must carry out to establish EEIs is illustrated in Figure 6.5.
Figure 6.5: Process of Data Collection and Establishment of EEIs
EEC = energy efficiency and conservation, EEI = energy efficiency indicator, GDE = General Department of Energy.
Source: Author.
0
100
200
300
400
500
600
700
800
900
- 100 200 300 400 500 600 700 800 900
BEI vs GFA for medium-sized malls
Verification, resubmission, interpretation,
assessment, and benchmarking
Submission, validation, and analysis
EEC Authority
GDE
- Dept of Energy Technique & Energy Business Policy
Submission, compilation, and validation of data
Verification and resubmission of
data
Analysis of data
Interpretation and assessment of EEI
Benchmarking
70
5.1. Commercial sector
The EEIs in the commercial sector are intensities, which are defined as the ratio of yearly energy
consumption (measured in energy unit, kWh) to gross floor area (measured in square metres). To
differentiate this EEI from that of the industry sector, this ratio is referred to as building energy intensity
(BEI) in this report and is referred to under level 2 in Figure 6.6. For meaningful comparison, the BEI values
are to be compared amongst the same building sub-sector or building category. In other words, the BEIs
of office buildings, retail malls, hotels, hospitals, etc. are compared within the same category or type of
buildings. The reason for this is that different building categories have different operation functions.
Therefore, the BEIs should be compared within the same building category for an ‘apple-to-apple’
comparison. The BEIs are computed at the sub-sector level and are computed as follows:
𝐵𝑢𝑖𝑙𝑑𝑖𝑛𝑔 𝐸𝑛𝑒𝑟𝑔𝑦 𝐼𝑛𝑡𝑒𝑛𝑠𝑖𝑡𝑦 =𝑌𝑒𝑎𝑟𝑙𝑦 𝑒𝑛𝑒𝑟𝑔𝑦 𝑐𝑜𝑛𝑠𝑢𝑚𝑝𝑡𝑖𝑜𝑛
𝐺𝑟𝑜𝑠𝑠 𝑓𝑙𝑜𝑜𝑟 𝑎𝑟𝑒𝑎
Where: 1) Yearly energy consumption is the total energy usage in a building in 1 year
2) Gross floor area is the gross build-up area of a building including common areas such as
reception area, corridors inside buildings, etc. but exclude any covered carpark area
Figure 6.6: Pyramid of Commercial Sector Indicators
BEI = building energy intensity, TFC = total final consumption.
Source: Produced by author based on IEA (2014a).
Level 1a: Total sectoral energy consumption (absolute or as a share of TFC)
Level 2b: Share of each energy source total sector energy consumption mix
Level 2: Total energy consumption per floor area defined as BEI
Level 3: End-use energy consumption by services (absolute or as a share of
building energy consumption)
71
The establishment of commercial sector EEI focuses on level 2, which is to produce BEIs by building sub-
sector, such as office buildings; hotels (one- to three-star rated, and four- to five-star rated); retail
buildings or shopping malls (large, medium-sized, and small); and hospitals (large, medium-sized, and
small).
Each of these building sub-sectors is expected to have different levels of energy intensities, which are
mainly due to different building functions and operating hours; hence, they will have different BEI
benchmark values. The level of energy intensities in hotels is expected to be different for four- to five-star
rated hotels because the level of services and amenities available in such hotels is expected to be more
energy intensive than one- to three-star rated hotels. Therefore, hotel category should be further
classified under these two categories.
Similarly, retail buildings should be subdivided under low-end and high-end malls; and hospitals should
be subdivided under large, medium-sized, and small so that data collection, analyses of data, and
establishment of EEIs can be more accurately carried out. It is suggested that the GDE, in consultation
with stakeholders, establish these subcategories after reviewing the statistical information on the sizes of
these types of buildings.
Table 6.2: Suggested Minimum BEI Values for Building Sub-sectors
Category of Buildings Indicative BEI Benchmark Valuea
(kWh/m2/y)
Remarks
Office buildings 150 Suggested minimum entry level BEI value for office building
Hotels 200 (3-star and below)
290 (4-star and above)
The classification of hotel is based on the hotel industry’s classification
Retail buildings 240 (low-end outlets)
350 (high-end outlets)
Classification of retail buildings under low end and high end to be established by the GDE in consultation with stakeholders
Hospitals 200 (small/medium)
290 (large)
Classification of retail buildings under small, medium-sized, and large to be established by the GDE in consultation with stakeholders
a Suggested minimum BEI values given in Table 6.2 are based on Malaysia’s Green Building Index entry level BEI values and are subject to further analyses and verification upon the establishment of EEIs in Cambodia. Source: Green Building Index, Malaysia, www.greenbuildingindex.org.
5.2. Industry sector
Like the commercial sector, the development of industry sector EEIs is pyramidal but focusing on level 2
of industry sector energy consumption per unit of sub-sector physical output. Figure 6.7 illustrates the
pyramid of industry sector indicators. The most aggregated level refers to the overall energy consumption
72
of the industry sub-sector expressed either in absolute or as a share of industry sector consumption under
level 1a, and the share of each energy source in the total sub-sector consumption mix. These two
indicators, although not intensities, provide an overview of sub-sectoral energy consumption. However,
the establishment of industrial EEIs focuses on level 2a. The establishment of level 2b on industrial sub-
sector energy consumption per value added would require factories to submit data on the value of
production output, which represents the measure of the contribution of the sub-sector to the GDP. The
possibility of this aspect of data submission needs to be addressed. Hence, the establishment of level 2b
EEIs is left to the GDE’s planning, upon further deliberations, on whether level 2b EEIs can be developed.
Figure 6.7: Pyramid of Industry Sector Indicators for Sub-sectors
Source: Produced by author based on IEA (2014a).
Level 2a industry sector EEIs are energy intensities for industrial sub-sectors such as textiles, food and
beverages, breweries, and cement, etc. The EEI is a ratio of sub-sector energy consumption to production
output, which can be computed as follows:
𝐼𝑛𝑑𝑢𝑠𝑡𝑟𝑖𝑎𝑙 𝑠𝑢𝑏𝑠𝑒𝑐𝑡𝑜𝑟 𝐸𝐸𝐼 =𝑌𝑒𝑎𝑟𝑙𝑦 𝑠𝑢𝑏𝑠𝑒𝑐𝑡𝑜𝑟 𝑒𝑛𝑒𝑟𝑔𝑦 𝑐𝑜𝑛𝑠𝑢𝑚𝑝𝑡𝑖𝑜𝑛
𝑌𝑒𝑎𝑟𝑙𝑦 𝑝𝑟𝑜𝑑𝑢𝑐𝑡𝑖𝑜𝑛 𝑜𝑢𝑡𝑝𝑢𝑡
Where:
1) Yearly sub-sector energy consumption is the total energy consumption including the use of all
energy sources for production processes only (excluding fuel for transportation) as illustrated in
Figure 6.8.
Level 1a: Total sub-sector energy consumption absolute or as a share of
industrial consumption
Level 1b: Share of each energy source in total sub-sector energy consumption mix
Level 2a: Sub-sector energy consumption per unit of physical output
Level 2b: Sub-sector energy consumption per value added
Level 3a: For each process/product type: energy consumption per unit of physical output
Level 3b: For each process/product type: energy consumption per value added
73
2) The denominator is the activity data, which is the yearly production output in terms of weight,
volume, or other unit deemed most suitable by respective factories.
Figure 6.8: Typical Energy Flow and Utilisation in Industrial Production Process
Source: Author and Ir. Luk Chau Beng.
To establish industrial EEIs, the industry sector refers to the manufacture of finished goods and products,
as listed under ‘manufacturing industries’ within the United Nations International Recommendations on
Energy Statistics. Accordingly, this sector excludes upstream power generation; refineries; and
distribution of electricity, gas, and water. In line with IEA’s energy balance on the industry sector, the list
excludes mining and quarrying of raw materials, as well as construction industry (IEA, 2014a).7 Therefore,
the industrial sub-sectors considered for EEI establishment would cover textiles and leather, food,
beverages, and tobacco including breweries, non-metallic minerals including cement and ceramic
products, wood and wood products, pulp and print, iron and steel, non-ferrous metals, chemical including
fertilisers, rubber and plastic products, machinery, transport equipment, etc. The final list is subject to
GDE’s planning upon further deliberations. Nevertheless, the classification of the industrial sub-sectors
should be based on the International Standard Industrial Classification adopted by Cambodia.
5.3. Residential sector
Unlike the commercial and industry sectors, the establishment of residential sector EEIs does not depend
on the collection of data through the regulatory or mandatory requirements of submitting data by
homeowners. However, like the commercial sector, the development of residential sector EEIs is
’pyramidal’ but focusing on level 2a of residential sector energy consumption per dwelling. Figure 6.6
illustrates the pyramid of residential sector EEIs. Therefore, residential energy consumption per dwelling
7 Refer to ‘What does the industry sector mean and cover?’, IEA (2014a).
Energy Electrical energy
Electricity billing
Self-generation (diesel genset)
Thermal energy
Biomass, waste heat, solar etc.
Fuel oil, coal, LPG, etc.
74
is the recommended EEI for the overall residential sector. However, in addition to the overall EEIs, the
development of EEIs should be classified under type of dwellings, i.e. houses, apartments, etc.
Figure 6.9: Pyramid of Residential Sector Indicators
TFC = total final consumption. Source: Produced by author based on IEA (2014a).
Level 1a on total residential energy consumption, level 2a EEIs on per dwelling basis, and level 2b on per
capita basis can be developed from the data of the Electricite du Cambodge (EDC). Level 2a EEIs can be
used for the analysis and home energy reporting presented in Section 5.7 of this report. Level 1b on energy
consumption mix, level 2c on residential energy per floor area, and level 3 on end-use energy consumption
by appliance will require residential energy consumption survey.
6. Publication of Energy Consumption Data at the National Level
Having successfully collected and processed data and established EEIs, the task would not be complete if
such useful information is not suitably disseminated nationwide. Energy consumption data and EEIs may
be compiled and published in national energy statistics; websites; EEI promotion booklets; press releases;
conferences and workshop; governmental and trade association publications; dialogue meetings with
trade, professional, and academic bodies, etc. Feedback to the commercial and industry sectors, and, to
some extent, the residential homeowners via home energy reporting (refer to Section 5.7) would be
extremely useful for achieving national energy-saving targets.
To safeguard the interests of business entities and to publish reliable information, the following principles
are recommended:
Level 1a: Total residential energy consumption (absolute or as share of TFC)
Level 1b: Share of each energy source in total residential energy consumption mix
Level 2a: Total residential energy consumption per dwelling
Level 2b: Total residential energy consumption per capita
Level 2c: Total residential energy consumption per floor area
Level 3: End-use energy consumption (absolute or as a share of residential consumption
75
1) Ensure that the processed data are of good quality.
2) Published information should be precise and useful without ambiguity such that readers do not
need to interpret the data. The publication should include trending graphs or charts, and any
assumptions and basis used in the analyses. The graphs or charts should be simple and easy to
understand.
3) The publication of EEIs should be aggregated to industrial or building sub-sector basis without
publishing the names of business entities. In fact, only the trending of EEIs and/or average value
should be published instead of the individual EEIs of each business entity. EEI benchmark values
for the respective sub-sectors can be established and published after sufficient collection of data
covering a few years. Such benchmark values should be deliberated on and accepted by
stakeholders when the GDE is ready for such analyses and deliberation.
4) Ensure that the energy consumption information and indicators are reviewed and updated
periodically before the next release of information.
7. Road Map (2020–2025)
Data collection to establish the EEIs is an important part of the EEC plan. According to the IEA, energy
efficiency has the unique potential of simultaneously contributing to long-term energy security, economic
growth, and even improved health and well-being as greenhouse gas (GHG) emissions can be reduced
through the adoption of energy efficiency practices. To be effective in implementing EEC plans, it is
important to develop and maintain reliable EEIs to achieve the following objectives:
1) To better inform the policy process and help decision makers develop policies that are best suited
to meet domestic and/or international objectives;
2) To better inform and prompt business entities to explore energy-efficient measures that will save
energy and improve energy productivity in their respective work premises, i.e. efficient use of
energy resources.
The success of data collection for establishing the EEIs depends on the following factors:
1) the establishment of regulatory or mandatory requirements;
2) yearly budget and workforce resources of the implementation department or agency; and
3) effective planning.
Accordingly, recommended road-map activities for data collection and EEI establishment are given in
Table 6.3. It is assumed that the establishment of regulatory or mandatory requirements is addressed
separately from the planning of data collection and EEI establishment. Some of the proposed activities
may be carried out in parallel whilst some activities may be carried forward to the following year. As
highlighted in Section 6.4, EEIs, including BEI benchmark values, should only be established after
continuous collection and analyses of data for at least 3 years.
76
Table 6.3: Recommended Road Map for 2020–2025 Activities
Phase
Description of Activity Remarks
Phase 1a: 2020–2021 The GDE to head the formation of a task force to plan and design data collection and assessment formats
The task force may include key stakeholders from the commercial and industry sectors, and professional and academic bodies.
Phase 1b: 2020–2021 Establishment of an EEC resource centre with progressive increase of qualified and trained staff to spearhead collection, processing, and analyses of data
The GDE must estimate the number of designated premises required under the regulatory requirements and identify organisational structure and workforce required.
Phase 2a: 2021–2022 Conduct of technical workshops/forums to disseminate EEC measures, mandatory requirements, data collection to establish EEIs
Stakeholders from the business entities need to be informed and explained about energy management reports and data submission.
Phase 2b: 2021–2025 Collection, processing, validation, and analysis of data
Collecting, processing, and validating the data will be a continuous process.
Phase 3a: 2022–2025 Analysis and establishment of EEIs Analysing and establishing EEIs will be a continuous process.
Phase 3b: 2023–2025 Further analysis and establishment of EEI benchmarking values, including engagement with stakeholders
After establishing sufficient EEIs, benchmarking values for the respective sub-sectors will be developed to drive the EEC agenda.
EEC = energy efficiency and conservation, EEI = energy efficiency indicator, GDE = General Department of Energy
Source: Author.
References
Energy Conservation Center, Japan (EECJ) (2006), Japan Energy Conservation Handbook 2005/2006
Tokyo: EECJ.
Green Building Index, Malaysia, www.greenbuildingindex.org.
International Energy Agency (IEA) (2014a), IEA Energy Efficiency Indicators: Fundamentals Statistics
2014. Paris: IEA. https://www.iea.org/reports/energy-efficiency-indicators-fundamentals-on-
statistics.
International Energy Agency (IEA) (2014b), IEA Energy Efficiency Indicators: Essentials for Policy Making
2014. Paris: IEA. https://www.iea.org/reports/energy-efficiency-indicators-essentials-for-policy-
making.
77
Theangseng, H. (2019), GDE MME, Power Development Plan presented at the Working Group meeting
on the Preparation of Energy Outlook and Analysis of Energy Saving Potential in East Asia
Region, 17–20 December 2019.
78
Chapter 7
Conclusions and Policy Recommendations
Shigeru Kimura, Leong Siew Meng, Han Phoumin
1. Conclusions
Energy efficiency and conservation (EEC) will be significant in curbing the growth of energy demand and
contribute to energy savings and security, whilst maintaining economic growth in the country and
applying appropriate EEC policies. Cambodia is one of the fast-growing energy demand countries in ASEAN
due to its robust economic growth since 1990s. Thus, an appropriate energy efficiency master plan will be
needed in the country to encourage EEC investment and behavioural change of energy consumers under
the EEC regulations, so-called the EEC Act. This master plan, based on a practical and effective approach,
comprises six chapters summarised as follows:
Chapter 1 specifies the sub-decree or regulations on energy efficiency to lay out the legal and
organisational framework for activities in the field of energy efficiency and aims to create conditions to
reduce energy consumption. In this case, the sub-decree or regulation guide the Ministry of Mines and
Energy (MME) and relevant agencies to develop a comprehensive policy and regulatory framework to
achieve energy efficiency in all sectors. The EEC sub-decree or regulations aim to promote energy
efficiency as part of country’s sustainable development by developing and applying a system of activities
and measures for (i) the improvement of energy efficiency at the end-use level, (ii) the introduction of
schemes of obligations for energy savings, (iii) the development of the market of energy efficiency services
and encouragement of provision of energy efficiency services, and (iv) the introduction of financial
mechanisms and schemes supporting the fulfilment of the national objective of energy efficiency.
Needless to say, the EEC sub-decree describing the legal framework is important for establishing energy
service companies (ESCOs), developing energy managers, standards and labelling, education and
campaigns, and preparation of EEIs, which are referred henceforth as the five EEC policies and
programmes.
Chapter 2 explains the role of an ESCO, its scope of services, and its importance in the implementation of
EEC in Cambodia. The two ESCO business models are presented in the chapter as well: shared saving
energy performance contract (EPC) and guaranteed saving EPC. Specific contents with useful information
are also provided for the following topics: (i) registration and licensing, (ii) financial Incentives, (iii) ESCO
business model, and (iv) a case study for an EPC project in Malaysia. The road map to planning and
implementing the establishment of ESCOs in Cambodia are also mentioned. ESCOs have a huge potential
role in reducing the country’s energy consumption and, therefore, greenhouse gas (GHG) emissions. They
play a key role in addressing energy shortages and price increases.
Chapter 3 describes and addresses the needs, duties, and methodology in developing energy managers
to support the implementation of EEC in Cambodia. The specific content of this chapter includes (i) the
requirements, duties, and expectation of an energy manager; (ii) the formation of the CEM (certified
79
energy managers) advisory committee to drive the registration and licensing requirements of CEM – which
are minimum qualifications, certification syllabus, certification process and registration, licensing and
renewal; (iii) mandatory training and international support to kick-start the capacity development of
energy managers and train local EEC experts as future local trainers; (iv) formation of an association of
energy managers to create a strong working relationship between government regulators (the General
Department of Energy [GDE]) and the designated premise owners, to develop members’ welfare, and to
continuously raise the standard of CEMs’ competencies and skills to achieve EEC goals; (v) 5-year
implementation road map for developing energy managers. CEMs are essential and responsible to
effectively and efficiently manage energy in designated premises to ensure that energy use is fully
optimised. Proper selection of suitable personnel who have influence and are accepted by both
management and colleagues and have further qualifications with EEC skills and knowledge through
training, certification, and continuous development are the key attributes towards successful
implementation of EEC management programmes.
Chapter 4 explains the electrical equipment use in promoting energy efficiency by achieving a minimum
energy performance standards (MEPS) that, in turn, will reduce the overall power consumption of the said
premises, especially households. With MEPS in place, an energy labelling system shall be used, and
registration of the equipment shall be done based on the labelling categories. Specific contents are also
provided for the following topics: (i) identification of relevant institutions, (ii) selection of targeted
appliances, (iii) testing bodies, and (iv registration of MEPS and energy labelling. The road map to roll out
the various stages of the MEPS requirements and energy labelling is also mentioned.
Chapter 5 discusses various communication and promotional methods for education and campaigns
through public and professional forums, media campaigns like printed media with practical EEC
information, websites and TV broadcast, home energy reporting, school system, and publicity campaigns
through national awards. Specific contents with useful and practical information are also provided for the
following topics: (i) school syllabus, (ii) media campaigns, (iii) pamphlets for EEC promotion, and (iv) home
energy report. A road map to roll out various education and campaign activities in phases is also discussed.
In general, the successful planning and implementation of education and promotion campaign activities
will require both technical input and committed government support.
Chapter 6 explains the concept of establishing energy efficiency indicators (EEIs), which requires the
collection of quality energy and activity data from designated premises in the commercial and industry
sectors. Regulatory requirements and designated premises for the commercial and industry sectors are
explained. Although the definition of designated premises has been suggested to be based on 3,000,000
kWh/year (or 10 mil MJ/year), further deliberation and review should be made to establish an acceptable
threshold value. This value will affect the number of commercial buildings and industrial premises that
will be required to submit energy management reports with relevant energy consumption and activity
data. The chapter also defines the EEIs for the commercial, residential, and industry sectors, with
methodologies including validation and analyses that are based on the concept of energy efficiency
indicators pyramid of the International Energy Agency (IEA). The establishment of EEIs is focused on
developing sub-sector energy intensity. The importance of developing the EEIs and subsequently
benchmark values for each industrial sub-sector, commercial building sub-sector, and each household per
80
area or district basis has been highlighted. The EEIs and benchmark values for the respective sub-sectors
will prove to be particularly important and useful for policymakers and the GDE. Publication of energy
consumption data nationwide and a road map to roll out phased activities are discussed in this chapter.
Appendix A discusses the case study on the review of energy saving potential in the existing chiller system
of a 250-room hotel. This case study demonstrates a method of reviewing and analysing the electricity
consumption of the existing chiller system after conducting a walk-through audit and obtaining relevant
energy consumption data. The case study was able to identify and analyse the saving potential in chiller
replacement with a new and high efficiency chiller and auxiliary equipment. The case study shows
reasonable return on investment. More importantly, it provides a useful example of how a walk-through
audit can generate useful information and findings on the potential benefits of EEC applications.
2. Recommendations
The GDE will be a key player in promoting EEC in Cambodia. Thus, improvement of the EEC department
under the GDE will be a top priority, such as allocating more human and financial resources under the EEC
sub-decree. The EEC department of the GDE should work on and prioritise the five EEC policies and
programmes mentioned above.
The GDE should start the education and campaign programme by firstly collaborating with Cambodian
energy managers. The purpose of the programme is to make Cambodians aware of the EEC; in other
words, instilling the EEC in the people’s mind through media campaigns. The programme will request
Cambodians to apply simple EEC measures – such as frequent switching off of appliances, minimising
standby power, reducing the leaking of cool air, installing simple shading devices in buildings, etc. The
programme will target reducing waste in electricity consumption in the industry, commercial, and
residential sectors. As a second step, the GDE will introduce EEC education in schools and in communities
through the school syllabus and EEC leaflets, respectively.
The GDE is also reminded to develop many local energy managers quickly through domestic and/or EEC
lecture courses to the candidates. The GDE shall certify and issue the EEC licence to the candidates who
qualified in domestic and foreign examinations on EEC. Developing energy managers will surely contribute
to the increase in opportunities for energy audits to measure energy consumption in industries and
buildings. These audits will help realise the energy saving potential in Cambodia.
The GDE should invite ESCOs, including foreign ESCOs such as from Malaysia and Thailand, to Cambodia’s
energy market quickly because they will be the key players in conducting EEC consultations to factories
and commercial buildings through expedited programmes, such as energy audits. The GDE, in
collaboration with the Ministry of Industry and Handicraft, will license the candidates of ESCOs in
Cambodia, who send their application forms to the GDE. The country’s energy sector is attractive for
ESCOs because energy prices are relatively higher than in neighbouring countries due to the absence of
energy subsidies. However, the GDE will initially support ESCOs to give them business opportunities
through the conduct of energy audits in government buildings.
81
Standard and labelling (S&L) system is an important EEC policy for the GDE. However, realising this system
will take time because the GDE will surely facilitate a testing lab in Cambodia. The department will also
establish MEPS for each electricity-intensive appliance such as air conditioner, refrigerator, microwave
oven, etc. But linking the S&L system with education and campaign will significantly contribute to saving
energy across the sectors, especially in the residential sector. The GDE must start preparing the S&L
system to focus on its institutional recognition aspects.
The EEIs are especially useful in measuring the effectiveness of energy use and energy saving amounts
achieved through the implementation of EEC policies and programmes. But the EEIs are determined,
based on analyses of energy end-use consumption surveys or data collected from the industry and
commercial sectors, after approval of an EEC sub-decree or the EEC Act. For example, the GDE will first
designate factories and commercial buildings for the survey and collect detailed energy consumption data
from the designated entities. This is to determine the EEIs of factories, defined as energy consumption
divided by production and EEIs of buildings as energy consumption divided by floor area. The GDE must
start preparing the survey or data collection by selecting factories and buildings to be designated,
designing the questionnaire, etc.
82
Annex
Case Study: Potential Energy Savings of a Hotel’s Chilled-water Air-
conditioning System
Leong Siew Meng and Lee Yuen How
A case study was carried out at a hotel in Phnom Penh to review and investigate whether its chilled-water
air-conditioning system has energy saving potential. In view of the non-disclosure agreement with the
hotel, this report on the findings will not reveal the name of the hotel, which had contributed useful
information for this study. Nevertheless, we acknowledge with appreciation the hotel management’s
cooperation in granting permission to visit the air-conditioning facilities and in making energy
consumption records available.
This case study aims to explore any energy saving potential in an existing chilled-water system that has
operated for more than 20 years. In view of improved and energy-efficient chillers available in the market,
the case study would focus on making a preliminary assessment of the chiller operation. Hotels, operating
for 24 hours, would likely have energy saving potential. How this case study was conducted is equivalent
to a walk-through audit without any measurement taken; only basic information was obtained. The hotel
has 250 rooms, and the technical information obtained is summarised as follows:
• Chillers installed:
o 2 units of 1,000 refrigerator tons (RT) centrifugal chillers
o 1 unit of 400 RT screw compressor chiller
• Monthly electricity consumption data is presented in Figure A1.
• Electricity tariff is US$0.16/kWh
The monthly electricity consumption of the hotel’s air-conditioning system from November 2018 to
October 2019 was consistent, except for March to May in 2019 (Figure A1). April and May 2019 recorded
a dip in electricity consumption. This was because of electricity rationing during these 2 months, which
was due to the extremely dry weather that time. Supply of electricity was restricted during this period.
The hotel had to generate its own electricity using diesel generator sets during the power outage. The
monthly electricity consumption shown in Figure A1 did not include the self-generated electricity because
the power generated was to cater mainly to lighting and essential services. The air-conditioning service
had to be shut down for a brief period in 2019 during the staggered power rationing arrangement per
day. The air-conditioning service was turned on again after the electricity supply was restored during the
day. Although the highest consumption per month was recorded in December 2018 (Figure A1), the
highest average daily consumption occurred in February 2019 (Figure A2). This was due to the shorter
83
month of February, hence, the highest average daily consumption of 12,985 kW/day. This highest average
daily consumption was used to estimate the average daily chilled-water generation load in terms of
refrigeration ton and the daily chiller load profile on a worst-case basis.
Figure A1: Monthly Electricity Consumption (2018–2019)
Source: Author, based on the monthly electricity bills provided by the hotel.
379.351 396.519
371.085 363.590
313.414
270.090 272.888
359.934
387.790
371.623 365.768
385.437
374.392 353.124
-
50.000
100.000
150.000
200.000
250.000
300.000
350.000
400.000
450.000
Mo
nth
ly E
lect
rici
ty C
on
sum
pti
on
(kW
h)
84
Figure A2: Average Daily Electricity Consumption (2018–2019)
Source: Author, computed from the monthly electricity consumption provided by the hotel.
Figure A3: Average Daily Chilled-water Generation in RT (2018–2019)
RT = refrigerator ton. Source: Author, estimated from the highest daily electricity consumption of 12,985 kWh that occurred in February 2019, as shown in Figure A2.
12.645 12.791 11.970
12.985
10.110
9.003 8.803
11.998 12.509
11.988 12.192 12.433 11.619
-
2.000
4.000
6.000
8.000
10.000
12.000
14.000
Nov-18 Dec-18 Jan-19 Feb-19 Mar-19 Apr-19 May-19 Jun-19 Jul-19 Aug-19 Sep-19 Oct-19
Ave
rage
Dai
ly E
lect
rici
ty C
on
sum
pti
on
(k
Wh
)
439 444
416
451
351
313 306
417 434
416 423 432
Overall average RT
-
50
100
150
200
250
300
350
400
450
500
Nov-18 Dec-18 Jan-19 Feb-19 Mar-19 Apr-19 May-19 Jun-19 Jul-19 Aug-19 Sep-19 Oct-19
Ave
rage
RT/
day
85
Figure A4: Estimated Daily Chiller Load Profile Derived from Chilled-water Generation (in RT)1
RT = refrigerator ton. Source: Author, based on the highest daily electricity consumption in Figure A3 on worst-case basis.
Average daily electricity consumption for each month was computed and is shown in Figure A2. Based on
the daily electricity consumption, it is possible to estimate the daily chilled-water generation requirement
in terms of refrigerant tons (Figure A3). For estimation purposes, the average system efficiency was
assumed to be 1.2 kW/RT (based on industry experience for old water-cooled system and discussion with
hotel staff). The average daily chilled-water generation capacities in terms of refrigeration tons were
estimated (based on system efficiency of 1.2 kW/RT) (Figure A3). The highest daily average chiller load
was 451 RT, which occurred in February 2019 (Figure A3).
Based on the worst-case scenario of 451 RT that occurred in February 2019 (for highest cooling load
demand situation), an estimated daily load profile was computed as illustrated in Figure A4. For a detailed
study, the proper method is to conduct an energy audit, which would include data logging of a full-day
operation of the chiller/s. The purpose of a load profile is to assess the daily cooling load requirements
and determine the peak load demand for more accurate chiller selection. Figure A4 shows that the cooling
load fluctuates during the daily operation of chillers. The peak load is expected to reach about 610 RT,
which usually occurs in mornings and evenings, as described by the hotel operations staff. During the
morning and evening operation, it would be necessary to operate the 1,000 RT chiller.
Based on the estimated peak load, a new chiller is selected to compare and evaluate a chiller replacement,
in order to examine whether there is any potential to save energy. With this in mind, the following new
1 Figure A4 is not based on measured hourly loads but an estimated load profile, which was based on the highest estimated daily average chiller load of 451 RT that occurred in February 2019 as shown in Figure A3.
Average 451 RT
0
100
200
300
400
500
600
700
07
00
08
00
09
00
10
00
11
00
12
00
13
00
14
00
15
00
16
00
17
00
18
00
19
00
20
00
21
00
22
00
23
00
00
00
01
00
02
00
03
00
04
00
05
00
06
00
Ch
iller
Lo
ad (
RT)
Time (typical day in February 2019: worst-case basis)
Daily average 451 RT (Feb-2019)
86
chiller configuration is identified and is used as a basis for comparing with the performance of the existing
system:
Proposed new chiller system configuration:
a) New chiller: Daikin magnetic 550 RT chiller
Chiller efficiency: 0.575 kW/RT, power input of 316 kW, rated at
chilled water 54/440F, condenser water 87/970F
b) Existing chiller: 1 x 400 RT screw compressor chiller
1 x 1,000 RT centrifugal chiller (optional to retain one unit of existing
1,000 RT chiller, which would become redundant, but hotel operation
expressed preference to retain one unit for operation on rotation basis.
c) Retrofitting of new cooling towers, piping, AHUs and FCUs to be installed.
d) Estimated cost of chiller: US$380,000
e) Estimated retrofitting work: US$700,000
f) Estimated design and supervision fee: US$170,000
This new chiller configuration is expected to efficiently generate chilled water for the hotel’s air-
conditioning requirements. For estimation and comparison purposes, the hotel’s air-conditioning
requirements are estimated using industrial practice (rule-of-thumb method) of 2.0 RT maximum cooling
load per hotel room, which is estimated slightly on the high side for a 4-star hotel. For proper assessment,
the engineering designer’s method of evaluating the hotel cooling load requirements – based on the
physical dimensions, building orientation, hotel rooms configuration and construction, facilities and
amenities – would need to be carried out to compute for more accurate total cooling load requirements.
However, for the purpose of this case study, the following are estimated:
1) Estimated daily maximum cooling load: 250 𝑥 2 = 500 RT
2) Estimated average daily cooling load requirement: 500 𝑥451
610= 370 𝑅𝑇 ∗
Note: * The ratio of 440:600 was taken from Figure A4 to compute the average daily cooling
load, based on the estimated peak load of 500 RT
3) Assuming a system efficiency at 0.75 kW/RT, the estimated daily chiller plant electricity
consumption: 370 RT x 0.75 kW/RT x 24 = 6,660 kWh
4) Assuming hotel occupancy rate of 85% (for conservative estimates), estimated new yearly
electricity consumption: 6,660 x 365 x 0.85 = 2,066,265 kWh
5) Estimated cost of new electricity cost: 2,066,265 x US$0.16 = US$330,602/y
87
The above estimated electricity consumption of the proposed system is compared with the existing
records of electricity consumption as follows:
1) Based on the records of total electricity consumption from November 2018 to October 2019:
4,237,489 kWh/y
2) Estimated electricity cost of existing operation: 4,237,489 x US$0.16 = US$677,998/y
3) Estimated electricity saving: 4,237,489 − 2,066,265 = 2,171,224 kWh/y
4) Estimated electricity cost savings: US$677,998 – US$330,602 = US$347,396
5) Estimated cost of new chiller, retrofitting and design/supervision work:
380,000 + 700,000 + 170,000 = US$1,250,000
6) Estimated simple payback period: 1,250,000
347,396= 3.6 years
Figure A5: Cash Flow for Case Study
IRR = internal rate of return.
Source: Shigeru Kimura and Leong Siew-Meng.
Based on the estimated yearly electricity savings and estimated investment costs, the cash flow and
internal rate of return (IRR) were computed (Figure A5). The IRR is estimated to be 25% and the breakeven
would occur in the fourth year after project commencement. The cumulative savings in the tenth year of
(1.250.000)
(902.604)
(555.209)
(207.813)
139.583
486.978
834.374
1.181.770
1.529.165
1.876.561
2.223.957
(1.500.000)
(1.000.000)
(500.000)
-
500.000
1.000.000
1.500.000
2.000.000
2.500.000
0 1 2 3 4 5 6 7 8 9 1 0
Ret
urn
on
Inve
stm
en
t(U
S$)
YEAR (project commencement @year #0)
IRR = 25%
88
operation is expected to be about US$2.224 million. Based on the above, the case study shows that the
proposed replacement of old chillers and auxiliary equipment appears to be a viable project. The above
assessment was based on the following assumptions:
a) Hotel occupancy rates remain the same every year throughout the period of IRR analysis as that
of the study period (i.e. November 2018 to October 2019).
b) The estimation of the new electricity consumption was based on 85% hotel occupancy rate.
c) The electricity tariff remains constant at US$0.16 throughout the period of IRR analysis.
However, the above computation did not consider the following (in addition to previously
mentioned exclusions):
1) Operations and maintenance costs
• Such costs are assumed to be about the same between the old and new systems, although
the manufacturer claims that the maintenance cost of magnetic chillers is lesser due to
its state-of-the-art magnetic bearing with oil-free technology and, hence, no requirement
for oil change, associated shutdown, and savings incurred on oil accessories compared
with conventional chillers.
• The magnetic chiller is expected to provide higher operational savings as it can retain high
energy efficiency on part-load operation, compared with lower energy performance at
part-load operation for old and conventional chillers (as illustrated in Figure A6). Higher
chiller efficiency would yield greater energy savings. Chillers that are highly energy
efficient at part-load would suit hotel operations in view of the cooling load fluctuations
due to seasonal demands and the fluctuating daily cooling loads. Therefore, the chillers
are expected to operate on part-load conditions.
89
Figure A6: Comparison of Energy Performance of Chillers at Part-load and Full-load Operations
between Magnetic Chillers and Conventional Chillers
Source: Daikin Applied (Malaysia) Sdn Bhd.
• Consequential operational loss was not considered in the above cash flow and IRR
analysis.
2) Costs of demolition work due to unforeseen site conditions
• The cost of retrofitting work was only an estimation but the extent of demolition work
requirements and constraints at the existing site would require thorough investigations
and site survey. The estimated cost of retrofitting work does not include interior design
work.
• However, some of the costs may be defrayed by possible resale value of the existing
chiller/s subject to the hotel’s decision whether to retain any existing chiller.
Summary of Case Study
Despite some limitations of this case study, there are some interesting findings summarised as follows:
1) Through a walk-through audit and available energy consumption and other basic data, energy
saving potential can be identified and quantified.
2) This case study demonstrates a method to make a preliminary analysis of energy savings and
indicative project viability.
3) Chiller replacement of old units can offer potential energy savings and reasonable return on
investment.
90
4) Walk-through audit can generate useful information and directions for more detailed studies.
Energy audit is necessary to determine a project’s viability for investment decisions.
5) This case study shows that EEC case studies or demonstration projects can showcase the
benefits of EEC measures.
Acknowledgements
This case study was facilitated by the following parties:
1) Daikin Malaysia Sdn Bhd (Branch of Cambodia), Goh Lam Yong
2) Daikin Applied (Malaysia) Sdn Bhd, Chea Suei Keong
3) GA Aircon, Phnom Penh, Cambodia, Sokkheng Min